METHOD FOR DETERMINING DESIRED CELL TYPE USING EXPRESSION OF miRNA AS INDICATOR

ABSTRACT

A method is provided for distinguishing living cells in a living state with high accuracy. Provided is a method for distinguishing a desired cell type from a cell group comprising two or more types of cells, using the expression of miRNA as an indicator, wherein the method comprises the following steps: (1) a step of introducing mRNA comprising a marker gene operably linked to the target sequence of miRNA used as an indicator into a cell group; and (2) a step of distinguishing a cell type, using the translation level of the marker gene as an indicator.

RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 15/110,503, filed Oct. 5, 2016, which is a 35 U.S.C. § 371 national phase application of PCT Application PCT/JP2015/050467, filed Jan. 9, 2015, which claims priority to Japanese Application No. 2014-003726, filed Jan. 10, 2014. The entire contents of each are incorporated herein by reference in its entirety.

STATEMENT REGARDING ELECTRONIC FILING OF A SEQUENCE LISTING

A Sequence Listing in ASCII text format, submitted under 37 C.F.R. § 1.821, entitled 5576-323CT ST25.txt, 226,734 bytes in size, generated on Feb. 4, 2020, and filed via EFS-Web, is provided in lieu of a paper copy. This Sequence Listing is hereby incorporated by reference into the specification for its disclosures.

FIELD AND BACKGROUND OF THE INVENTION

The present invention relates to a method for distinguishing a desired cell type using the expression of miRNA as an indicator.

The tissues or organs of a multicellular organism are composed of many types of cells. The human body is composed of approximately 60 trillion (6×10¹³) cells, and there are 411 cell types known, even if only mature cells are considered. With regard to these cells, not only a technique of analyzing the function of each cell, but also a technique of distinguishing or identifying a cell type in preparation of cells for medical application has become important.

In order to identify a cell, a means for detecting a ligand that is specifically expressed on a cell surface, using an antibody, has been generally known. However, in order to detect intracellular information using an antibody, it is necessary to immobilize a target cell and/or to allow the cell to permeate through a membrane. Thus, detection using an antibody has been problematic in that it cannot be applied to fractionation of living cells. In addition, a receptor capable of specifying a cell is not necessarily present on the cell surface. Moreover, a means for classifying one factor into two factors, positive/negative (negative or positive) (i.e., a qualitative classification means), such as ligand detection using an antibody, has been problematic in that detectable combinations are limited, and thus, it is difficult to carry out a refined classification.

As a method for more specifically classifying cells, that is, as a method for quantitatively classifying cells, for example, the profiling of cells based on multivariate measurement using a microarray, next-generation sequencing, etc. has been known. In these methods, with regard to an intracellular molecule such as a protein or RNA, many types of molecules are simultaneously subjected to a quantitative measurement, or are subjected to statistical analysis such as multivariate analysis, so that the cells can be quantitatively classified. However, since the measured cells are destroyed, this method is problematic in that it is impossible to measure cells in a live state.

As a target that can be an indicator for identifying cells, microRNA (hereinafter referred to as “miRNA”) has attracted attention. As a means for detecting miRNA in living cells, a reporter assay, which is carried out by introducing a reporter construct comprising DNA or a virus into cells, has been used. However, by such a method, it is likely that the reporter construct will be incorporated into the genome of a host cell and remain. Thus, the cells identified by this method will cause problems in medical application. Moreover, detection of miRNA according to the conventional reporter assay has been directed to searching for the target gene of the miRNA, and it has not been used to identify cells.

SUMMARY OF THE INVENTION

It has been desired to develop a method for distinguishing cells, with high accuracy in a live state.

The present inventors have found that a desired cell type can be distinguished from a cell group comprising two or more types of cells by quantitatively obtaining information regarding the expression of miRNA in living cells, using mRNA having a specific structure, thereby completing the present invention.

Specifically, according to one embodiment, the present invention relates to a method for distinguishing a desired cell type from a cell group comprising two or more types of cells, using the expression of miRNA as an indicator, wherein the method comprises the following steps: (1) a step of introducing mRNA comprising a first marker gene operably linked to the target sequence of miRNA used as an indicator into a cell group; and (2) a step of distinguishing a cell type, using the translation level of the first marker gene as an indicator.

In the method, the step (1) is preferably a step of simultaneously introducing the target sequence of miRNA used as an indicator and two or more mRNAs comprising different first marker genes into cells.

In the method, the desired cell type is preferably a cell type in which the expression level of miRNA used as an indicator is low, and the step (2) is preferably a step of distinguishing a cell type in which the translation level of the first marker gene is high. In the method, the desired cell type is preferably a cell type in which the expression level of miRNA used as an indicator is high, and the step (2) is preferably a step of distinguishing a cell type in which the translation level of the first marker gene is low.

In the mRNA used in the method, the target sequence of the miRNA is preferably linked to the 5′-terminal side of the first marker gene.

In the method, the determination is preferably carried out using a flow cytometer.

In the method, the determination is preferably carried out using an image analyzer.

It is preferable that the method further comprise a step of screening for miRNA used as an indicator, which is specific to the cell type, before the step (1).

Moreover, according to another aspect, the present invention relates to a kit for distinguishing a cell, which comprises mRNA comprising a first marker gene operably linked to the target sequence of miRNA used as an indicator.

According to the present invention, by utilizing, as an indicator, the activity of miRNA that is intracellular information, a cell type can be distinguished with high resolution. Since the method according to the present invention can be applied in a live state, it is particularly advantageous in that cells can be used for various intended uses, in particular, for medical use, after completion of the determination. Moreover, since the method of the present invention can be carried out by introducing mRNA into a group of cells and this mRNA is decomposed with a half-life of approximately 1 day and is promptly removed from the inside of the cell, the present method does not cause problems such that viral infection or DNA remaining in the cells would give damage to the genome. Furthermore, the method of the present invention is also advantageous in a simple detection method using a cytometer. In particular, by introducing the synthesized mRNA into cells, a detection error in the activity used as an indicator could be reduced, separation ability could be improved, and it becomes possible to carry out high-accuracy determination. As an effective application of the present invention, for example, upon differentiation of pluripotent stem cells into specific cells, a desired cell type is distinguished from pluripotent stem cells with desired properties, or from a cell group obtained by inducing differentiation from the pluripotent stem cells, so that the desired cells can be classified, isolated or selectively eliminated.

Further, even in a case in which there is only a slight difference in terms of the expression of miRNA used as an indicator among a plurality of cell types comprised in a cell group, for example, even in a case in which the difference is approximately 1.5-fold or less, the method of the present invention is able to distinguish these cells from one another by using two mRNAs comprising first marker genes operably linked to the target sequences of at least two miRNAs used as indicators. This is based on the findings that the activity ratio of reporter proteins expressed from two co-introduced mRNAs is constant in a cell population and has little variation. Further, by increasing the types of such co-introduced mRNAs, it becomes possible to distinguish a larger number of cells based on a larger number of indicators.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1, panels (a), (b) and (c) is a view schematically describing the technique of the present invention whereby two different types of cells are separated on a dot plot plane of flow cytometry, and a conventional technique.

FIG. 2, panels (a) and (b) includes histograms showing a signal rate obtained in a case in which miRNA-responsive reporter mRNA or control mRNA is introduced into two different types of cell types.

FIGS. 3A to 3D include a series of views showing the two-dimensional separation of existing cell lines using one or two types of miRNA-responsive reporter mRNAs.

FIG. 3E includes histograms showing the ratio of two fluorescence signals and graphs showing the cumulative curve of two types of miRNA-responsive reporter mRNAs.

FIGS. 3F to 311 includes views showing the two-dimensional separation of a mixture of two types of existing cell lines using one or two types of miRNA-responsive reporter mRNAs, and histograms showing the ratio of two fluorescence signals.

FIG. 4, panels (a) to (f) includes a series of views showing the two-dimensional separation or three-dimensional separation of existing cell lines using three types of or four types of miRNA-responsive reporter mRNAs.

FIGS. 5A and 5B include a series of views showing the three-dimensional separation of three types of cell lines using four types of control mRNAs.

FIGS. 5C and 5D include a series of views showing the three-dimensional separation of three types of cell lines using four types of miRNA-responsive reporter mRNAs.

FIG. 6 is a view showing the influence of the insertion site of a miRNA target sequence upon the translational efficiency of miRNA-responsive reporter mRNA.

FIG. 7, panels (a) and (b) is a view showing that miRNA-responsive reporter mRNA does not have inhibitory effects on intracellular miRNA activity.

FIG. 8, panels (a), (b) and (c) includes graphs showing the translational efficiency of the selected 20 types of miRNA-responsive reporter mRNAs in three types of cell lines.

FIGS. 9A to 9C include a series of views showing the two-dimensional separation of two types of cell lines using two types of miRNA-responsive reporter mRNAs.

FIGS. 9D to 9F include a series of views showing the two-dimensional separation of two types of cell lines using two types of miRNA-responsive reporter mRNAs.

FIGS. 9G and 911 is a view showing the two-dimensional separation of a mixture of two types of cell lines using two types of miRNA-responsive reporter mRNAs.

FIG. 10, panels (a), (b) and (c) is a view showing the colored images of cells and the two-dimensional separation of existing cell lines, in a determination method using an imaging analyzer.

FIGS. 11A to 11D is a view showing two-dimensional separation using three types of miRNA-responsive reporter mRNAs according to flow cytometry and imaging cytometry.

FIGS. 11E to 1111 is a view showing two-dimensional separation using miRNA-responsive reporter mRNAs linked to three types of nuclear localization signal genes according to flow cytometry and imaging cytometry.

FIGS. 12A to 12C is a view showing the results obtained by screening for miRNA-responsive reporter mRNA used for separation of IMR-90 in Example 9, and the results of a flow cytometric analysis in which miRNA-responsive reporter mRNAs have been co-introduced into IMR-90 with or without TGF stimulation.

FIGS. 12D and 12E is a view showing the results of FIG. 12C, and FIG. 12F, in the form of histograms.

FIG. 12F is a view showing the results of an imaging cytometric analysis in a case in which miRNA-responsive reporter mRNAs for expressing nuclear localized reporter proteins have been co-introduced into IMR-90 with or without TGF stimulation.

FIG. 13, panels (a) to (e) is a view showing the results obtained by screening for miRNA-responsive reporter mRNA used for separation of NHLF in Example 10, and the results obtained by analyzing separation of the cell population NHLF, using an mRNA set responding to miRNA having a high positive correlation to the cell population NHLF, or using an miRNA set that does not have such a high positive correlation.

FIG. 14, panels (a) and (b) is a view showing the results obtained by comparing the result of a first screening between the cell line (IMR-90) and primary cultured cells (NHLF).

FIG. 15, panels (a), (b) and (c) is a view schematically showing the results assumed in a case in which there is a distribution of two miRNA activities in a certain cell group, when the certain cell group has assumed to incorporate the same amount of mRNA as the other.

FIG. 16 is a view showing the results obtained by co-introducing four types of miRNA-responsive mRNAs, which have been selected based on the results of a second screening, into IMR-90, wherein the results are shown in the form of a three-dimensional density plot.

FIG. 17A is a view showing the results of an imaging cytometric analysis in a case in which control miRNA (hmAG1-M9) and miRNA-responsive reporter mRNA (α(miR-145-5p)-hmKO2-M9) have been co-introduced into IMR-90 without TGF-β1 stimulation (-TGF-β1; left view) or with TGF-β1 stimulation (+TGF-β1; right view). In the figure, Bright Field indicates a phase-contrast image; hmAG1 indicates the fluorescence image of hmAG1; APC indicates the stained image of aSMA antibody; hmKO2 indicates the fluorescence image of hmKO2; Hoechist indicates a nuclear-stained image; and ratio indicates an overlapped fluorescence image.

FIG. 17B is a view showing the results of a flow cytometric analysis, in a case in which control mRNA (hmAG1-M9) and miRNA-responsive reporter mRNA (α(miR-145-5p)-hmKO2-M9) have been co-introduced into IMR-90 without TGF-β1 stimulation (-TGF-β1: green) or with TGF-β1 stimulation (+TGF-β1:violet).

DETAILED DESCRIPTION OF EMBODIMENTS

Hereinafter, the present invention will be described in detail in the following embodiments. However, the scope of the present invention is not intended to be limited to these embodiments.

According to a first embodiment, the present invention relates to a method for distinguishing a desired cell type from a cell group comprising two or more types of cells, using the expression of miRNA as an indicator. The determination method according to the present embodiment comprises the following steps: (1) a step of introducing mRNA comprising a first marker gene operably linked to the target sequence of miRNA used as an indicator into a cell group; and (2) a step of distinguishing a cell type, using the translation level of the first marker gene as an indicator.

The cell group used as a target in the determination method of the present invention is a cell group comprising two or more types of cells. This cell group may be either a cell group collected from multicellular organism species, or a cell group obtained by culturing isolated cells. The cell group is particularly a cell group comprising two or more types of somatic cells collected from mammals (e.g. a human, a mouse, a monkey, a swine, a rat, etc.), or a cell group obtained by culturing cells isolated from mammals or mammalian cell lines. Examples of the somatic cells include keratinizing epithelial cells (e.g. keratinized epidermal cells), mucosal epithelial cells (e.g. epithelial cells on a tongue surface layer), exocrine epithelial cells (e.g. mammary gland cells), hormone secreting cells (e.g. adrenomedullary cells), cells for metabolism/storage (e.g. liver cells), inner luminal epithelial cells constituting a boundary surface (e.g. type I alveolar cells), inner luminal epithelial cells in the inner chain tube (e.g. vascular endothelial cells), cells having cilia with transport ability (e.g. respiratory tract epithelial cells), cells for extracellular matrix secretion (e.g. fibroblasts), contractile cells (e.g. smooth muscle cells), cells of blood and immune system (e.g. T lymphocytes), cells regarding senses (e.g. rod cells), autonomic nervous system neurons (e.g. cholinergic neurons), cells supporting sensory organs and peripheral neurons (e.g. satellite cells), nerve cells and glial cells in the central nervous system (e.g. astroglial cells), pigment cells (e.g. retinal pigment epithelial cells), and the progenitor cells thereof (tissue progenitor cells). The degree of differentiation of cells, the age of an animal from which cells are collected, etc. are not particularly limited. Both undifferentiated progenitor cells (including somatic stem cells) and finally differentiated mature cells can be used as a source of somatic cells in the present invention. Herein, examples of the undifferentiated progenitor cells include tissue stem cells (somatic stem cells) such as neural stem cells, hematopoietic stem cells, mesenchymal stem cells, or dental pulp stem cells. In the present invention, the type of mammal as a source, from which somatic cells are collected, is not particularly limited, and it is preferably a human. In addition, a preferred cell group is a cell group, in which artificial operations are performed on prophase somatic cells after collection of the cells, and it may be a cell group that includes undesired cells. Thus, the cell group is, for example, a cell group comprising iPS cells prepared from the somatic cells, or a cell group obtained after differentiation of pluripotent stem cells such as ES cells or iPS cells, which may include differentiated cells other than desired cells. In the present embodiment, the cell group as a determination target is preferably in a survival state. In the present invention, the expression “cells in a survival state” is used to mean cells in a state in which they maintain metabolic capacity. The present invention is advantageous in that, after cells have been subjected to the method of the present invention and the determination method has been then terminated, the cells remain alive without losing their original properties, and can be used in the subsequent intended use, in particular, while maintaining division capacity.

In the method of the present invention, the “desired cell type” to be distinguished means a group of cells, which is classified from other cell types, using the expression of miRNA as an indicator. In particular, the desired cell type means a certain group of cells having common properties, in terms of miRNA activity, which will be described in detail later. In the present invention, such a certain group of cells, which is classified from other cell types, using miRNA as an indicator, is also referred to as “homologous cells.” The desired cell type distinguished by the method of the present invention may be one type, or two or more types, for example, three types, four types, five types, six types, seven types, or eight types or more. Theoretically, the distinguish-possible cell type is not limited, and according to the present invention, 100 or more types of cells can be distinguished simultaneously.

In the present invention, the expression “to distinguish a desired cell type” is used to mean that the detectable signal information of desired specific one or more cell types, which are different from other cell types, is presented from a cell group comprising two or more types of cells, and in particular, that visually recognizable information is presented. It is to be noted that the visually recognizable information is not limited to emission of visual signals directly from cells, but it also includes information obtained by converting signals emitted from cells to visually recognizable information, using numerical values, charts, images, etc. Thus, the visually recognizable information means information visually recognizable by one skilled in the art. In the present description, the term “distinguish” may include the meanings that, after completion of the determination, the desired cell type is recognized, the desired cell type is distinguished, the desired cell type is identified, the desired cell type is classified, the desired cell type is isolated, undesired cell types are removed, the life or death of the desired cell type is distinguished, specific biological signals are detected or quantified in the desired cell type, and the desired cell type is fractionated based on specific physical or chemical signals. In the present invention, determination whereby a cell group, which has been unknown to comprise two or more types of cells, is distinguished to comprise different cell types by the method of the present invention, is also considered to be one aspect of determination of a desired cell type.

An aspect, in which a desired cell type is distinguished from a cell group comprising two or more types of cells, using the expression of miRNA as an indicator, includes the aforementioned various determination aspects, and also, this aspect is divided into a case in which the attribute regarding the “cell group comprising two or more types of cells” has previously been known to a certain extent, and a case in which there is no information regarding the attribute of the cell group.

The case in which the attribute regarding the cell group has previously been known to a certain extent means a case in which cell types comprised in the cell group have previously been specified to a certain extent by another method or the like. For example, there is a case in which specific cell types comprised in a specific cell group have previously been analyzed and predicted by the classification method using an antibody, or an Omics analysis/profiling method that is the profiling of cells based on multivariate measurement using a microarray, next-generation sequencing or the like, which have been described above as prior art techniques. Even in such a case, determination of a desired cell type in a live state by the method of the present invention is useful.

On the other hand, even in a case in which there is no information regarding the attribute of a cell group, the present invention is applicable.

There is a case in which a screening method applied in a step of screening for miRNA used as an indicator is different between the former case and the latter case. Such a screening step may be comprised as an optional pre-step in the method of the present invention. Details for the screening step will be described later.

In the method of the present invention, messenger RNA (mRNA) comprising a first marker gene operably linked to the target sequence of miRNA used as an indicator (hereinafter also referred to as “miRNA target sequence”) is used. In such mRNA, when specific miRNA is present, translation of the first marker gene is regulated depending on the abundance of such miRNA. Preferably, this is mRNA, in which when specific miRNA is present, the amount of a protein translated from the first marker gene (hereinafter referred to as a “marker protein”) is reduced by suppressing the translation of the first marker gene depending on the abundance of the miRNA.

The “expression of miRNA” in the present invention means that miRNA, in which mature miRNA interacts with a plurality of predetermined proteins to form an RNA-induced silencing complex (RISC), is present. The “mature miRNA” is single-stranded RNA (20 to 25 nucleotides), and it is generated from pre-miRNA as a result of extranuclear cleavage by Dicer, whereas the “pre-miRNA” is generated from pri-mRNA, which is single-stranded RNA transcribed from DNA by partial cleavage by an intranuclear enzyme called Drosha. The miRNA used in the present invention is selected from at least 10,000 or more types of miRNAs, as appropriate. More specifically, the present miRNA is selected, as appropriate, from miRNAs registered in database information (e.g., www.mirbase.org/ or www.microrna.org/), and/or miRNAs described in reference information stored in the database. That is to say, in the present invention, the miRNA used as an indicator is not limited to specific miRNA. The miRNA used as an indicator can be appropriately selected, depending on the properties of a cell type to be distinguished by the method of the present invention. Moreover, in particular, one miRNA or a combination of multiple miRNAs, which is expressed at a high level (high activity) in some cells and which is expressed at a low level (low activity) in other cells in a cell group as a determination target, is preferably selected. This is because separation accuracy can be further increased. Such miRNA or such a combination of multiple miRNAs can be selected by the after-mentioned screening method. Such miRNA used as an indicator is not limited to the miRNAs that had been specified at the time of filing of the present application, but it also includes all miRNAs, the presence and function will be specified in the future.

The miRNA target sequence means a sequence capable of specifically binding to the miRNA used as an indicator. For instance, the miRNA target sequence is preferably a sequence completely complementary to the miRNA used as an indicator. Otherwise, as long as the miRNA target sequence is recognizable by miRNA, it may also have a mismatch with the completely complementary sequence. The mismatch with the sequence completely complementary to the miRNA may be generally a mismatch, which is recognizable by the miRNA in a desired cell, and it is considered that there may be a mismatch of approximately 40% to 50% with regard to the original function of the cell in a living body. Such a mismatch is not particularly limited, and it is, for example, a mismatch of 1%, 5%, 10%, 20%, 30% or 40% of 1 nucleotide, 2 nucleotides, 3 nucleotides, 4 nucleotides, 5 nucleotides, 6 nucleotides, 7 nucleotides, 8 nucleotides, 9 nucleotides, 10 nucleotides or the entire recognition sequence. In addition, in particular, as with the miRNA target sequence on mRNA comprised by a cell, the target sequence may comprise a large number of mismatches in a portion other than a seed region, namely, in a region on the 5′-terminal side in the target sequence, which corresponds to approximately 16 nucleotides on the 3′-terminal side of miRNA. The seed region may not comprise such mismatches, or may comprise a mismatch of 1 nucleotide, 2 nucleotides, or 3 nucleotides.

The first marker gene is a gene encoding any given protein, which is translated in a cell, functions as a marker, and enables determination of a cell type. The protein, which is translated in a cell and is able to function as a marker, may be, for example, a protein, which can be visualized by fluorescence, luminescence or color development, or by supporting such fluorescence, luminescence or color development, and can be quantified. Examples of the fluorescent protein include: blue fluorescent proteins such as Sirius or EBFP; cyan fluorescent proteins such as mTurquoise, TagCFP, AmCyan, mTFP1, MidoriishiCyan, or CFP; green fluorescent proteins such as TurboGFP, AcGFP, TagGFP, Azami-Green (e.g. hmAG1), ZsGreen, EmGFP, EGFP, GFP2, or HyPer; yellow fluorescent proteins such as TagYFP, EYFP, Venus, YFP, PhiYFP, PhiYFP-m, TurboYFP, ZsYellow, or mBanana; orange fluorescent proteins such as KusabiraOrange (e.g. hmKO2) or mOrange; red fluorescent proteins such as TurboRFP, DsRed-Express, DsRed2, TagRFP, DsRed-Monomer, AsRed2, or mStrawberry; and near infrared fluorescent proteins such as TurboFP602, mRFP1, JRed, KillerRed, mCherry, HcRed, KeimaRed (e.g. hdKeimaRed), mRasberry, or mPlum, but examples of the fluorescent protein are not limited thereto.

An example of the luminescent protein is aequorin, but examples are not limited thereto. In addition, examples of the protein supporting fluorescence, luminescence or color development include enzymes decomposing fluorescence, luminescence or color development precursors, such as luciferase, phosphatase, peroxidase, or β lactamase, but examples of this protein are not limited thereto. In the present invention, when the protein supporting fluorescence, luminescence or color development is used as a first marker gene, determination of a desired cell is carried out by allowing a cell to come into contact with a corresponding precursor, or by introducing such a corresponding precursor into a cell.

Other examples of the protein capable of functioning as a marker in a cell include proteins, which have a direct influence on the function of cells. Specific examples of such a protein include a cell growth protein, a cell killing protein, a cell signaling factor, a drug resistance gene, a transcriptional regulator, a translational regulator, a differentiation regulator, a reprogramming inducer, an RNA-binding protein factor, a chromatin control factor, and a membrane protein, but examples of the protein are not limited thereto. For example, the cell growth protein allows only cells, in which the protein has been expressed, to grow, and then specifies growing cells, so that it functions as a marker. The cell killing protein causes cell death to cells, in which the protein has been expressed, and kills cells themselves that comprise or do not comprise specific miRNA, so that it functions as a marker for showing the life or death of the cells. The cell signaling factor functions as a marker, when cells, in which the factor has been expressed, emit specific biological signals, and these signals are then specified. Examples of the cell killing protein include Bax and Bim. As an example, the translational regulator recognizes the three-dimensional structure of specific RNA and binds thereto, and it thereby regulates translation of another mRNA into a protein, so that it functions as a marker. Examples of the translational regulator include 5R1,5R2 (Nat Struct Biol. 1998 jul; 5(7):543-6), B2 (Nat Struct Mol Biol. 2005 November; 12(11):952-7), Fox-1 (EMBO J. 2006 Jan. 11; 25(1):163-73.), GLD-1 (J Mol Biol. 2005 Feb. 11; 346(1):91-104.), Hfq (EMBO J. 2004 Jan. 28; 23(2):396-405), HuD (Nat Struct Biol. 2001 February; 8(2): 141-5.), SRP19 (RNA. 2005 July; 11(7): 1043-50), L1 (Nat Struct Biol. 2003 February; 10(2):104-8.), L11 (Nat Struct Biol. 2000 October; 7(10):834-7.), L18 (Biochem J. 2002 Mar. 15; 362 (Pt 3):553-60), L20 (J Biol Chem. 2003 Sep. 19; 278(38):36522-30.), L23 (J Biomol NMR. 2003 June; 26(2):131-7), L25 (EMBO J. 1999 Nov. 15; 18(22):6508-21.), L30 (Nat Struct Biol. 1999 December; 6(12):1081-3.), LicT (EMBO J. 2002 Apr. 15; 21(8):1987-97.), MS2 coat (FEBS J. 2006 April; 273(7):1463-75.), Nova-2 (Cell. 2000 Feb. 4; 100(3):323-32), Nucleocapsid (J Mol Biol. 2000 Aug. 11; 301(2):491-511.), Nucleolin (EMBO J. 2000 Dec. 15; 19(24):6870-81.), p19 (Cell. 2003 Dec. 26; 115(7): 799-811), L7Ae (RNA. 2005 August; 11(8): 1192-200.), PAZ (PiWi Argonaut and Zwille) (Nat Struct Biol. 2003 December; 10(12):1026-32.), RnaseIII (Cell. 2006 Jan. 27; 124(2):355-66), RR1-38 (Nat Struct Biol. 1998 July; 5(7):543-6.), S15 (EMBO J. 2003 Apr. 15; 22(8):1898-908.), S4 (J Biol Chem. 1979 Mar. 25; 254(6):1775-7.), S8 (J Mol Biol. 2001 Aug. 10; 311(2):311-24.), SacY (EMBO J. 1997 Aug. 15; 16(16):5019-29.), SmpB (J Biochem (Tokyo). 2005 December; 138(6):729-39), snRNP U1A (Nat Struct Biol. 2000 October; 7(10):834-7.), SRP54 (RNA. 2005 July; 11(7):1043-50), Tat (Nucleic Acids Res. 1996 Oct. 15; 24(20):3974-81.), ThrRS (Nat Struct Biol. 2002 May; 9(5):343-7.), TIS11d (Nat Struct Mol Biol. 2004 March; 11(3):257-64.), Virp1 (Nucleic Acids Res. 2003 Oct. 1; 31(19):5534-43.), Vts1P (Nat Struct Mol Biol. 2006 February; 13(2):177-8.), and λN (Cell. 1998 Apr. 17; 93(2):289-99.). Among these, more preferred translational regulators are MS2 coat and L7Ae.

In the present invention, the first marker gene may comprise a gene encoding a localization signal. Examples of such a localization signal include a nuclear localization signal, a cell membrane localization signal, a mitochondrial localization signal, and a protein secretion signal. Specific examples include a classical nuclear localization sequence (NLS), an M9 sequence, a mitochondrial target sequence (MTS), and an endoplasmic reticulum localization sequence, but examples are not limited thereto. Such a localization signal is particularly advantageous when the determination step in the method of the present invention is carried out on an image, in the after-mentioned imaging cytometry or the like.

In the present invention, when the translational regulator is used as a marker, mRNA having a second marker gene for which translation is regulated by the translational regulator is simultaneously introduced into a cell. An example of such mRNA having a second marker gene for which translation is regulated by the protein is mRNA having a second marker gene sequence operably linked to an RNA sequence, to which the protein capable of regulating the translation can bind. A specific example of such mRNA is mRNA disclosed in WO2009/066757 or WO2014/014122. The disclosures of these publications are all incorporated herein by reference. One skilled in the art could appropriately select mRNA having a second marker gene for which translation is regulated by a protein, which can be preferably used in the method of the present invention, by referring to the aforementioned publications. In the present invention, the same first marker genes as those described above can be used as second marker genes.

The mRNA used in the method of the present invention comprises a first marker gene operably linked to the target sequence of miRNA used as an indicator. In the description of the present invention, such mRNA is also referred to as “miRNA-responsive reporter mRNA. In the present invention, the phrase “a first marker gene is operably linked to the target sequence of miRNA” means that at least one miRNA target sequence is comprised in the 5′-UTR and 3′-UTR of an open reading frame encoding the first marker gene (including an initiation codon), and/or in the open reading frame. The mRNA preferably comprises, in the direction from the 5′-terminus to the 3′-terminus, a Cap structure (7-methylguanosine 5′-phosphate), an open reading frame encoding the first marker gene, and poly(A) tail, and also comprises, in the 5′-UTR, in the 3′-UTR, and/or in the open reading frame, at least one miRNA target sequence. The position of the miRNA target sequence in the mRNA may be either 5′-UTR or 3′-UTR, or may also be in the open reading frame (on the 3′-terminal side of the initiation codon). Otherwise, the mRNA may comprise miRNA target sequences in all of these positions. Accordingly, the number of miRNA target sequences may be 1, 2, 3, 4, 5, 6, 7, 8, or more.

Preferably, one miRNA target sequence is present in the 5′-UTR. This is because it can achieve efficient translational inhibition. At this time, the number of nucleotides and the type of nucleotides between the cap structure and the miRNA target sequence may be freely distinguished, as long as they do not include AUG serving as an initiation codon and do not constitute a stem structure or a steric structure. For instance, the cap structure and the miRNA target sequence can be designed, such that the number of nucleotides between the cap structure and the miRNA target sequence can be 0 to 50 nucleotides, and preferably 10 to 30 nucleotides. Moreover, the number of nucleotides and the type of nucleotides between the miRNA target sequence and the initiation codon may be freely distinguished, as long as they do not constitute a stem structure or a steric structure. The miRNA target sequence and the initiation codon can be designed, such that the number of nucleotides between the miRNA target sequence and the initiation codon is 0 to 50 nucleotides, and preferably 10 to 30 nucleotides. It has been confirmed that translational inhibition can be achieved, even if four miRNA target sequences are present in the 3′-UTR.

The miRNA-responsive reporter mRNA preferably comprises modified nucleotides such as pseudo uridine and 5-methylcytidine, instead of ordinary uridine and cytidine. This is because of reduction in cytotoxicity. Such modified nucleotides can be positioned independently or as a part of the mRNA, in both cases of uridine and cytidine. In the case of being comprised as a part, the nucleotides can be positioned randomly at any given ratio.

After the sequence of the miRNA-responsive reporter mRNA has been distinguished as described above, one skilled in the art is able to synthesize the miRNA-responsive reporter mRNA according to any existing genetic engineering method. In particular, the miRNA-responsive reporter mRNA can be obtained according to an in vitro transcription synthesis method, using template DNA comprising a promoter sequence as a template.

There is a case in which only one type of miRNA-responsive reporter mRNA is used, or there is another case in which two or more types of, for example, three types, four types, five types, six types, seven types, or eight types or more of miRNA-responsive reporter mRNAs are used, depending on the purpose of determination, a target, or the activity of miRNA used as an indicator. For example, in the case of using two or more types of miRNA-responsive reporter mRNAs, it is desirable that both miRNA target sequences and first marker genes comprised in individual miRNA-responsive reporter mRNAs be different from one another. In addition, in the case of using two or more types of miRNA-responsive reporter mRNAs, the number of miRNA target sequences comprised in the miRNA-responsive reporter mRNA, the distance of the miRNA target sequence from the 5′-terminus, and other structural characteristics of the miRNA-responsive reporter mRNA may be different among individual miRNA-responsive reporter mRNAs.

In the present invention, in the step of introducing miRNA-responsive reporter mRNA into a cell (hereinafter referred to as an “introduction step”), one or more types of miRNA-responsive reporter mRNAs are directly introduced into cells included in a cell group, by applying a lipofection method, a liposome method, an electroporation method, a calcium phosphate co-precipitation method, a DEAE dextran method, a microinjection method, a gene gun method, etc. In the case of introduction of two or more different types of miRNA-responsive reporter mRNAs, or in the case of using miRNA-responsive reporter mRNA and mRNA used as a control (hereinafter also referred to as “control mRNA”), a plurality of mRNAs are preferably co-introduced into a cell group. This is because the ratio of the activities of marker proteins expressed from the thus co-introduced two or more mRNAs is constant in a cell population. At this time, the amount of miRNA-responsive reporter mRNA introduced is different, depending on the type of a cell group, into which the mRNA is introduced, the type of the introduced mRNA, a method of introducing the mRNA, and the types of introduction reagents. In order to achieve a desired translation level, one skilled in the art can appropriately select these conditions. Herein, the term “control mRNA” is used to mean mRNA, which does not have a miRNA target site and encodes a marker gene that is different from the first marker gene encoded by the miRNA-responsive reporter mRNA. Also regarding the amount of the control mRNA introduced, one skilled in the art can appropriately select the aforementioned conditions to achieve a desired translation level.

When the miRNA-responsive reporter mRNA is introduced into a cell, the translation level of the first marker gene encoded by the miRNA-responsive reporter mRNA is regulated, for example, the translation level is suppressed, if certain miRNA is present as RISC in the cell. Such regulation of the translation level is quantitatively carried out depending on miRNA activity. In contrast, if the certain miRNA is not present in the cell, or if the certain miRNA is not present as RISC, the translation level of the first marker gene encoded by the miRNA-responsive reporter mRNA is not suppressed. Accordingly, the translation level of the first marker gene is different between a cell in which the certain miRNA is present as RISC and a cell in which it is not present. It is to be noted that, in the present description, the case in which the certain miRNA is present as RISC is also referred to as a “case in which miRNA activity is present.” On the other hand, control mRNA expresses a marker protein, regardless of miRNA activity. This is because, even if such control mRNA is introduced into a cell, translation is not regulated depending on the expression level of miRNA, since the miRNA target sequence is not present therein.

Subsequently, a step of distinguishing a cell, using the translation level of the first marker gene as an indicator (hereinafter also referred to as a “determination step”), is carried out. In the determination step, a cell is distinguished based on the aforementioned translation level of the first marker gene. That is, this step can be a step of distinguishing the desired cell type that is a cell in which the expression level of the miRNA used as an indicator is low and the translation level of the first marker gene is high, and/or a step of distinguishing a desired cell type that is a cell in which the expression level of the miRNA used as an indicator is high and the translation level of the first marker gene is low. Such a cell in which the expression level of the miRNA used as an indicator is low, or a cell in which the expression level of the miRNA used as an indicator is high, can be distinguished by obtaining the ratio of the translation levels of the first marker genes among cells belonging to a cell group comprising two or more types of cells. Herein, when a translational regulator is used as a first marker gene, a cell is distinguished based on the translation level of a second marker gene that has been simultaneously introduced into the cell. By utilizing the aforementioned mRNA having a second marker gene for which translation is suppressed by a first marker gene, the translation level of the second marker gene is proportional to the expression level of the miRNA used as an indicator. Specifically, in a case in which the desired cell type is a cell in which the expression level of the miRNA used as an indicator is low, a cell in which the translation level of the second marker gene is low is distinguished. On the other hand, in a case in which the desired cell type is a cell in which the expression level of the miRNA used as an indicator is high, a cell in which the translation level of the second marker gene is high is distinguished. Accordingly, when a cell killing protein is used as a second marker gene, for example, a cell in which the expression level of the miRNA used as an indicator is high can be specifically induced to undergo cell death, and can be eliminated.

Specifically, the determination step can be carried out by detecting signals from a marker protein, employing a predetermined detection apparatus. Examples of the detection apparatus include a flow cytometer, an imaging cytometer, a fluorescence microscope, a luminescence microscope, and a CCD camera, but examples are not limited thereto. As such a detection apparatus, one skilled in the art can use a suitable apparatus, depending on a marker protein and the aspect of determination. For instance, when the marker protein is a fluorescent protein or a luminescent protein, it is possible to quantify the marker protein using a detection apparatus such as a flow cytometer, an imaging cytometer, a fluorescence microscope or a CCD camera. When the marker protein is a protein supporting fluorescence, luminescence or color development, a method of quantifying the marker protein using a detection apparatus such as a luminescence microscope, a CCD camera or a luminometer can be applied. When the marker protein is a membrane localization protein, a method of quantifying the marker protein using a detection reagent specific to a cell surface protein, such as an antibody, and the aforementioned detection apparatus, can be applied, and also, a method of isolating cells without performing the process of quantifying the marker protein, such as a magnetic cell separation device (MACS), can be applied. When the marker protein is a drug resistance gene, a method, which comprises detecting the expression of the first marker gene by administration of a drug and then isolating living cells, can be applied.

An example of a preferred detection method, which is applied when the marker protein is a fluorescent protein, is flow cytometry. In the flow cytometry, the intensity of light emitted from a fluorescent protein, luciferase, that is a marker protein translated in each cell, can be provided as information for determination. Hereafter, the aspect of determination of a cell type, in which flow cytometry is applied and one or more miRNA-responsive reporter mRNAs are used, will be described in several cases.

a. Separation Based on Expression Intensity, in which miRNA-Responsive Reporter mRNA is Used

According to one aspect of the present invention, only one type of miRNA-responsive reporter mRNA is used. Referring to FIG. 1, panel (a) for example, the values of fluorescence intensity obtained in the case of introducing only one type of miRNA-responsive reporter mRNA into a desired cell group have an inverted V-shaped distribution, as shown on the paper, outside of the graph plane. This is because there is a variation in the number of mRNAs introduced into individual cells in the target cell group. For example, when translation from miRNA-responsive reporter mRNA is suppressed depending on the miRNA activity in a desired cell, such an inverted V-shaped distribution of desired cells is moved to the left. When the distribution of the fluorescence intensity values obtained from the desired cell group is not overlapped with the distribution of the fluorescence intensity values obtained from another cell group, the desired cell group can be separated from the other cell group by separating only those having specific fluorescence intensity values, and thus, can be distinguished. Otherwise, as shown on the paper of FIG. 1, panel (a), even if the distribution of the fluorescence intensity values is overlapped with another distribution, a region on the edge with no overlapping of the distributions is distinguished, and cells can be separated.

b. One-Dimensional Separation, in which miRNA-Responsive Reporter mRNA and Control mRNA are Used

According to one aspect of the present invention, only one type of miRNA-responsive reporter mRNA is used, and control mRNA can be co-introduced into a cell. It can be said that translation of the first marker gene in the control mRNA is constant depending on the type of a cell, without being affected by miRNA. The control mRNA can be designed and prepared in the same manner as that for the miRNA-responsive reporter mRNA, with the exception that the control mRNA does not have a miRNA target site. In the present description, the term “dimension” is used to mean a “dimension” regarding the translation ratio of marker genes, and in particular, the ratio of the measured fluorescence intensity values.

In the present invention, when the miRNA-responsive reporter mRNA and the control mRNA are co-introduced, the ratio of the activities of marker proteins expressed from the two types of mRNAs is found to be constant in a cell population and has a small variation. Accordingly, by obtaining the ratio of the fluorescence intensities of marker proteins expressed from the two types of mRNAs, the expression ratio of specific mRNA in each cell can be obtained.

The expression ratio of marker proteins is almost constant among homologous cells, but there is a certain amount of variation. This is because of the following reasons.

(1) There is a slight variation in terms of miRNA expression level even among homologous cells.

(2) There is also variation in terms of the reaction rate of the expressed miRNA with the co-introduced mRNA.

(3) There is also variation in terms of the cell introduction ratio of the co-introduced two mRNAs.

Consequently, there is a case in which a certain extent of difference is generated in terms of the expression ratio of marker proteins, even among homologous cells. In the case of measurement by flow cytometry, such homologous cells are distributed in a belt shape having a certain width, in a dot plot in which the expression intensity of a marker protein encoded by the miRNA-responsive reporter mRNA is set on the X-axis and the expression intensity of a marker protein encoded by the control mRNA is set on the Y-axis. This width is caused by the aforementioned variation. When a plurality of belt-shaped plots corresponding to the number of different cell types appear and these are separated, these cells can be distinguished. As an example, in a case in which the measurement is carried out by flow cytometry in the determination step, in a dot plot in which the expression intensity of a first marker protein encoded by a first miRNA-responsive reporter mRNA is set on the X-axis and the expression intensity of a second marker protein encoded by a second miRNA-responsive reporter mRNA is set on the Y-axis, the homologous cells are distributed in a belt shape having a certain width. Such an aspect is schematically shown in FIG. 1, panel (a). In FIG. 1, panel (a), three belt-shaped plot groups are present. On the paper, the belt-shaped plots in the upper left and the lower right indicate two different types of cell groups, which have been distinguished on a dot plot plane by co-introduction of two types of miRNA-responsive reporter mRNAs. The belt-shaped plot in the center schematically shows the expression intensity of a marker protein when only the control mRNA is introduced into the same cell group as that described above for a control experiment, and two different types of cell groups cannot be distinguished on the dot plot plane.

In the separation shown in FIG. 1, panel (a), a case in which a first miRNA-responsive reporter mRNA that targets miRNA (a) and a second miRNA-responsive reporter mRNA that targets miRNA (b) are used for example, will be described. When cell A and cell B are classified using these mRNAs, separation ability becomes high, if miRNA (a) is highly expressed (high activity) in the cell A and miRNA (b) is highly expressed (high activity) in the cell B. In other words, separation ability becomes high, if the translation of miRNA (a)-responsive mRNA is suppressed in the cell A and the translation of miRNA (b)-responsive mRNA is suppressed in the cell B. In FIG. 1, panel (a), the arrow going from right to left along the X-axis in the figure and the arrow going from up to down along the Y-axis on the paper each indicate translation inhibition in the different direction. When it is assumed that regarding the first miRNA-responsive reporter mRNA, the translation inhibition of the cell A is α-fold (α>1) stronger than the cell B, and regarding the second miRNA-responsive reporter mRNA, the translation inhibition of the cell B is β-fold (β>1) stronger than the cell A, the cell A can be distinguished from the cell B on the dot plot of flow cytometry, if α×β is approximately 1.9-fold or more. If it is preferably 2.0-fold or more, and more preferably 2.5-fold or more, the cell A can be more clearly distinguished from the cell B. In another aspect, determination can be carried out by developing a histogram based on the ratio of two fluorescence values obtained from two mRNAs (e.g. the lower left histogram of FIG. 1, panel (a)). By performing determination using such a ratio, a difference in the mRNA introduction efficiency among cells can be canceled.

The resolution of the cell type in such an aspect will be further described. FIG. 2 is a view schematically showing the principle of the present invention by which the cell type A is distinguished from the cell type B with high resolution. In the aforementioned FIG. 1, panel (a), when fluorescence intensity is observed in a plurality of different miRNA-responsive reporter mRNAs, those fluorescence intensities are observed in the form of separated belts on the dot plot of flow cytometry. This demonstrates that the ratio of a plurality of fluorescence intensity values (lower left of FIG. 1, panel (a)) gives a better separation. That is to say, when two types of mRNAs are introduced, two types of fluorescence intensity values can be measured, and one type of fluorescence intensity ratio can be obtained. Thus, the target cells are distributed one-dimensionally (on a number line of fluorescence intensity ratio) and are separated. FIG. 2, panel (a) is a histogram showing a signal rate obtained when miRNA-responsive reporter mRNA and control mRNA are each introduced into two different cell groups A and B. Herein, a case in which the width of the distribution of fluorescence intensity ratio, namely, the width of a belt shown on a dot plot is 4-fold is assumed. Referring to FIG. 2, panel (a), it is found that if there is a difference of 4-fold between the cells A and B, in terms of the translational efficiency of the miRNA-responsive reporter mRNA obtained as a quantitative ratio of marker proteins (i.e., the activity of the miRNA), it is possible to separate the two types of cell groups from each other on the histogram.

c. One-Dimensional Separation Using Two Types of miRNA-Responsive Reporter mRNAs

In another aspect of the present invention, two or more types of miRNA-responsive reporter mRNAs are preferably co-introduced into cells. This is because the separation ability of cells can be enhanced by using two or more types of miRNA-responsive reporter mRNAs. FIG. 2, panel (b) is a schematic view describing the present embodiment, which enables high resolution even in a case in which there is merely a slight difference in terms of translational efficiency. That is, it is demonstrated that, even if they are a first miRNA-responsive mRNA (fluorescence intensity FL1 obtained by flow cytometry), which has merely a difference in translational efficiency of approximately 2-fold in comparison to control mRNA when it is introduced into the cell A, and a second miRNA-responsive mRNA (fluorescence intensity FL2 obtained by flow cytometry), which has merely a difference in translational efficiency of approximately 2-fold in comparison to control mRNA when it is introduced into the cell B, it is possible to sufficiently separate the cells from each other by using these two types of miRNA-responsive reporter mRNAs. Herein, when it is assumed that regarding the first miRNA-responsive reporter mRNA, the translational inhibition of the cell A is α-fold (α>1) stronger than that of the cell B, and that regarding the second miRNA-responsive reporter mRNA, the translational inhibition of the cell B is β-fold (β>1) stronger than that of the cell A, it is considered that the cell A can be separated from the cell B, if the integrated value of α×β is greater than the distribution width of the certain cell type shown in FIG. 2 (in this figure, 4-fold as an example). The exemplified 4-fold width is considered to be a case in which a relatively wide width could be generated, that is, the case of high level of difficulty.

Referring to FIG. 2, panel (b), in the case of α>1 and β<1, a cell population moves in the same direction. In the figure, β corresponding to the right arrow (β>1) faces to the left in the case of β<1. For example, in this figure, even if the cell A moves to the left by 8-fold at α=8 and the cell B moves to the left by 2-fold at β=0.5, a width of 4-fold remains between the cells (integrated value: 8×0.5), and thus, the two cells are separated from each other. In this case, however, the separation becomes better, not when the second miRNA-responsive reporter mRNA, but reporter mRNA that does not respond to miRNA (β=1) is used (integrated value: 8×1).

On the other hand, upon considering separation of cells using a ratio histogram (FIG. 2), if certain miRNA-responsive mRNA is used, the peak of a cell population is not only shifted to the right and left, but the width of the cell population is also changed. For separation of cells, the entire distribution of cells is shifted to the right and left until it exceeds “the width of cell distribution.” However, the shift amount (difference) of the entire distribution is distinguished by the integrated value of aft Meanwhile, such a width of cell distribution is widened or narrowed also by a combination of two types of miRNA-responsive mRNAs (see Example 10 and FIG. 15). As such, it is assumed that there is a case in which the narrowing of the distribution width while sacrificing the entire shift amount is advantageous for separation of cells.

When cells are to be separated according to a prior art technique using two types of antibodies binding to different fluorochromes and a cell surface antigen, if fluorescence intensity is measured by flow cytometry in the same manner as that described above, a dot plot as schematically shown in FIG. 1, panel (c) is obtained. That is, there are many overlapped portions between the cell A and the cell B, and thus, it is impossible to separate these cells from each other with high accuracy. In contrast, by using miRNA-responsive reporter mRNA, and further, by using a combination of two or more types of miRNA-responsive mRNA such that, as described above, translational efficiency can be relatively suppressed in the aforementioned cells and it can be relatively increased in other cells, resolution can be enhanced.

d. Two-Dimensional Separation Using Three Types of miRNA-Responsive Reporter mRNAs

Moreover, by using three or more types of miRNA-responsive reporter mRNAs and co-introducing them into a plurality of cells, separation ability can be further enhanced based on the same principle as that described above. For instance, by introducing three types of mRNAs, three types of fluorescence intensity values can be measured, and two types of fluorescence intensity ratios can be obtained. Hence, target cells are two-dimensionally distributed (on a plane of fluorescence intensity ratio) and are separated. As an example, a case in which a first miRNA-responsive reporter mRNA targeting miRNA (a), a second miRNA-responsive reporter mRNA targeting miRNA (b), and a third miRNA-responsive reporter mRNA targeting miRNA (c) are co-introduced into two different types of cells A and B, will be described. The expression intensity of a first marker protein encoded by the first miRNA-responsive reporter mRNA measured by flow cytometry is defined as FL1; the expression intensity of a second marker protein encoded by the second miRNA-responsive reporter mRNA measured by flow cytometry is defined as FL2; and the expression intensity of a third marker protein encoded by the third miRNA-responsive reporter mRNA measured by flow cytometry is defined as FL3. When FL1/FL3 and FL2/FL3 are set on the X-axis and Y-axis, respectively, and a dot plot is produced, homologous cells appear not in the shape of a belt, but in the shape of a mass. Such an aspect is schematically shown in FIG. 1, panel (b). Two masses existing on a dotted line going from upper left to lower right on the paper in FIG. 1, panel (b) indicate dot plot masses observed by not using the third miRNA-responsive reporter mRNAs, but using control mRNA that does not respond to any miRNA. It can also be said that this indicates sections obtained by cutting the plane of FIG. 1, panel (a) with a large arrow going from upper left to lower right on the paper. In contrast, it is found that as a result of co-introduction of the third miRNA-responsive reporter mRNA and the subsequent translational regulation that has been performed in a further different direction depending on a difference in the activity of miRNA (c), two masses existing on the dotted line are translationally regulated in each different directions (upper right and lower left on the paper), and thus, that the cell A can be more clearly separated from the cell B on the dot plot plane. Also, when two-dimensional separation is carried out using three types of miRNA-responsive reporter mRNAs, identical separation results can be obtained, although the fluorescence intensity of any one of the three types of miRNA-responsive reporter mRNAs is set at FL3 in the aforementioned calculation.

According to the two-dimensional separation using three types of miRNA-responsive reporter mRNAs, it becomes possible to distinguish and separate 25 types to 60 types or more of different cells, in which the miRNA active state is different in a 2-fold unit. As described above, this is because, theoretically, two types of cells can be distinguished from each other on the dot plot of flow cytometry, if the integrated value of translational efficiency of two types of miRNA-responsive reporter mRNAs is 1.9-fold or more in two types of cells. Accordingly, the two-dimensional separation using three types of miRNA-responsive reporter mRNAs can be practically used for determination of cell type. For example, if there may be cells in which the active state of certain miRNA has a difference of 5 stages (by 2-fold), it is considered that two types of miRNA-responsive mRNAs and one type of control mRNA are simultaneously introduced into the cells, so that 5×5=25 types of cells can be separated from one another. Using three types of miRNA-responsive reporter mRNA, 5×5×5=125 types of cells can be separated from one another by calculation. However, in practice, since there is overlap, approximately 61 types of cells can be separated. This is shown in Example 2 and FIG. 4, panel (f).

e. Three-Dimensional Separation Using Four Types of miRNA-Responsive Reporter mRNAs

In the same manner as the aforementioned aspect d, it is also possible to carry out three-dimensional separation using four types of miRNA-responsive reporter mRNAs. That is to say, if four types of mRNAs are introduced into cells, four types of fluorescence intensity values can be measured, and three types of fluorescence intensity ratios can be obtained. Thus, target cells are three-dimensionally distributed (in the space of the fluorescence intensity ratio), and are separated from one another. As an example, a case in which a first miRNA-responsive reporter mRNA targeting miRNA (a), a second miRNA-responsive reporter mRNA targeting miRNA (b), a third miRNA-responsive reporter mRNA targeting miRNA (c), and a fourth miRNA-responsive reporter mRNA targeting miRNA (d) are co-introduced into two different types of cells A and B, will be described. The expression intensity of a first marker protein encoded by the first miRNA-responsive reporter mRNA measured by flow cytometry is defined as FL1; the expression intensity of a second marker protein encoded by the second miRNA-responsive reporter mRNA measured by flow cytometry is defined as FL2; the expression intensity of a third marker protein encoded by the third miRNA-responsive reporter mRNA measured by flow cytometry is defined as FL3; and the expression intensity of a fourth marker protein encoded by the fourth miRNA-responsive reporter mRNA measured by flow cytometry is defined as FL4. When FL1/FL4, FL2/FL4, and FL3/FL4 are set at X-axis, Y-axis, and Z-axis, respectively, and a dot plot is produced, homologous cells are each distributed in the form of a mass in a three dimensional space. Furthermore, a higher dimensional separation is theoretically possible, and if (n+1) types of different miRNA-responsive reporter mRNAs are used, (n+1) types of fluorescence intensity values can be measured, and an n type of fluorescence intensity ratios can be obtained. As a result, it becomes possible to separate multiple types of cells from one another in an n-dimensional space. In this case as well, it is necessary that both a miRNA target sequence and a first marker gene be different in (n+1) types of miRNA-responsive reporter mRNAs. In particular, in the case of separation using fluorescence intensity, an n type of marker proteins need to have a detectably different wavelength region.

An example of another detection method applied in the determination step of the present invention is imaging cytometry. Such imaging cytometry can be carried out using an image analyzer. The image analyzer is able to obtain information regarding a change over time of the translation level of a first marker gene in a cell, and is excellent in terms of imaging and visualization, and is also able to improve the analysis amount per unit time. In addition, the image analyzer is advantageous in that it can be applied to analysis including the morphological or positional information of cells, and identification of cells that targets cells adhering to a culture vessel or a cell group organized in a planar or steric manner.

Even in the case of using such an image analyzer, the fluorescence intensity ratios obtained from two or more types of miRNA-responsive reporter mRNAs are shown in the form of a dot plot on a plane, so that different cell types can be separated from one another, and the aforementioned aspects a to d can be carried out.

Further, by image processing, the fluorescence intensity ratios of cells are converted to color information, so that a determination step that can be more visually utilized can be created. Specifically, a plurality of miRNA-responsive reporter mRNAs are designed such that they comprise a sequence encoding a nuclear localization signal, such as M9. Thereby, a marker protein is translated such that it is fused with the nuclear localization signal in a cell, and the marker protein is localized in the nucleus of the cell, so that a clearer fluorescence image of cells can be obtained.

The method of the present invention preferably comprises a step of screening for miRNA used as an indicator, as an optional pre-step. In the screening step, one or more miRNAs having different activities in multiple types of cells, which are comprised or are predicted to be comprised in a “cell group comprising two or more types of cells” as a measurement target, are selected. This is because the aforementioned desired resolution is achieved. In particular, when cell types comprised in a cell group have previously been known to a certain extent, one miRNA, which is highly expressed (high activity) in a cell A and is expressed at a low level in another cell B, is selected. When two or more types of miRNAs used as indicators are selected, a combination of mRNAs, namely, a combination of miRNA (a), which is expressed at a high level (high activity) in a cell A and is expressed at a low level (low activity) in another cell B, and miRNA (b), which is expressed at a low level (low activity) in a cell A and is expressed at a high level (high activity) in another cell B, is selected. Then, miRNA target sequences are distinguished in miRNA-responsive reporter mRNAs, based on one or two or more miRNAs distinguished in such a step.

When cells comprised in a cell group are available as each isolated cells (e.g. cells A and cells B), the screening step can be carried out by a method comprising the following three steps. That is, in a first step, multiple types of miRNAs selected from a miRNA library are screened. For example, with regard to 60 to 70 types of miRNAs, miRNA-responsive reporter mRNA, which targets each miRNA and encodes an identical fluorescent protein, is prepared. Thereafter, each miRNA-responsive reporter mRNA and control mRNA encoding another fluorescent protein are co-introduced into each of existing cells A and B, and translational efficiency (a marker protein translated from the control mRNA/a marker protein translated from the miRNA-responsive reporter mRNA) is then measured.

In a second step, from the values of translational efficiency measured in the first step, 2 types, 3 types, or 4 types are combined with one another, and a vector constituted from those values is defined as each coordinate vector for the cell A and the cell B (e.g. XY coordinate, XYZ coordinate, or any given n-dimensional coordinate (wherein n represents an integer of 4 or greater)), and the distance between the cells in the ordinate is then calculated. When three or more types of existing cells are comprised, the shortest distance, among the distances between all types of two cells comprised, is calculated.

In a third step, two types, three types, or four types of miRNAs, which increase the distance between cells that has been calculated in the second step, are defined as target sequences, and one set of miRNA-responsive reporter mRNAs each encoding different fluorescent protein genes are prepared. The one set of miRNA-responsive reporter mRNAs are co-introduced into each of the cells A and B or into three or more types of cells, and separation ability is then tested. Among a plurality of sets, those from which the test results that the fluorescence ratio distributions of individual cells have appeared in each different regions and there has been small overlap among the distributions have been obtained, are preferably used in the subsequent introduction step and determination step.

On the other hand, in the case of a cell group regarding which a separation method different from the present invention has been known, the following operation is further needed: separation according to a different method is simultaneously carried out in the first step of the screening step, and the translational efficiency of each separated cell, namely, the value of miRNA activity is measured. Examples of such a separation method different from the present invention include: a method, which comprises immobilizing cells upon separation, performing membrane permeation, and detecting an intracellular factor using an antibody, and a method which comprises previously modifying a gene even it is a living cell, and using a cell used for the purpose of the screening step (a reporter line, etc.). However, examples of the separation method different from the present invention are not limited thereto. The second step and the third step can be carried out in the same manners as those described above. The present screening method will be demonstrated in Example 9.

When multiple types of cells comprised in the “cell group comprising two or more types of cells” as a measurement target are unknown, the aforementioned screening step can be converted to the following screening step including the following first to fourth steps. In a first step, the miRNA activity value in the cell group is measured, and at the same time, a distribution of the miRNA activities of individual cells in the cell group is obtained. As a result, multiple types of miRNAs exhibiting a wide distribution of miRNA activities are selected. For example, it is preferable to select 6 to 10 types of miRNAs.

In a second step, a combination set of two types, three types, or fourth types of miRNAs is prepared from the miRNAs selected in the first step. In the second step, one set of miRNA-responsive reporter mRNAs, which targets two types, three types, or fourth types of miRNAs comprised in the one set, as target sequences, and encodes different fluorescent protein genes, is prepared.

In a third step, one set of miRNA-responsive reporter mRNAs, which is constituted with the two types, three types, or four types of miRNA-responsive reporter mRNAs prepared in the second step, is co-introduced into a cell group, and the correlation among miRNA activities in the cell group is then analyzed.

In a fourth step, one set of miRNA-responsive reporter mRNAs constituted with two types, three types, or four types of miRNA-responsive reporter mRNAs have been prepared again based on the correlation of miRNA activities analyzed in the third step, and the mRNAs are then co-introduced into the cell group to test separation ability. Among a plurality of sets, those, from which the test results that a distribution of fluorescence ratios in the cell group has been separated into two types, three types, four types, or more types of populations have been obtained, are preferably used in the subsequent introduction step and determination step. When such multiple types of cells comprised in the “cell group comprising two or more types of cells” are unknown, it can be said that the determination method of the present invention is a method of giving the definitions of a new cell type. The present screening method will be demonstrated in Examples 10 and 11.

As another optional pre-step, the present method may comprise a step of synthesizing miRNA-responsive reporter mRNA. In such a synthesis step, after miRNA used as an indicator or a combination of such miRNAs has been distinguished in the screening step, miRNA-responsive reporter mRNA or a combination of miRNA-responsive reporter mRNAs, which comprises miRNA target sequences that target them, is synthesized.

In addition, as a further optional step, the present method may comprise a step of separating cells after completion of the determination step.

In the aforementioned description, as a specific example of distinguishing cells, cases in each of which flow cytometry or imaging cytometry is applied in the determination step have been described. However, the present invention is not limited to the aforementioned aspects, and determination can be carried out theoretically in various aspects.

According to another aspect, the present invention relates to a kit for distinguishing a cell type, which comprises at least one type of miRNA-responsive reporter mRNA or a combination of two or more types of miRNA-responsive reporter mRNAs, and further comprises an optionally selected control mRNA. Such a kit may be prepared by enclosing the above-described miRNA-responsive reporter mRNA or combination of two or more types of miRNA-responsive reporter mRNAs in a preservable vessel or the like. Moreover, the present kit may comprise instructions regarding the use method thereof.

EXAMPLES

Hereinafter, the present invention will be described more in detail in the following Examples. However, these Examples are not intended to limit the scope of the present invention.

[Construction of Plasmid]

An IVT template for control tag RFP mRNA (SEQ ID NO: 24) (template DNA used for the synthesis of mRNA) was amplified from the plasmid pSRT-tagRFP according to PCR, using a primer set, T7Fwd5UTR and Rev120A. First, using a primer set, FwdMCS and RevMCS, the multicloning site of pGEM T-easy (Promega) was modified according to PCR-based site directed mutagenesis, so as to obtain a pAM empty vector. Subsequently, a DNA fragment prepared by digesting pCDFDuet-1 (Novagen) with NheI and AgeI was blunt-ended, and the resulting fragment was then inserted into a DNA fragment prepared by digesting pAM with DraI to prepare a pSM empty vector. Subsequently, in order to prepare a pSRT empty vector, a pair of oligo DNAs, Code 5UTR and Comp 5UTR, were annealed, and the resultant was then inserted into the EcoRI-NcoI site. Then, the annealed Code 3UTR and Comp 3UTR were inserted into a XbaI-HindIII site (or “fragment”). Finally, the coding sequence of tagRFP was amplified according to PCR using a suitable primer set, it was then digested with NcoI and BglII, and it was then inserted into the NcoI and BglII site of pSRT to obtain pSRT-tagRFP.

In order to fuse M9 as a nuclear localization signal with a fluorescent protein, the coding regions of hmAG1, hmKO2, and tagBFP were amplified using a suitable primer set, and the tagRFP region of pSRT-tagRFP was then substituted. Subsequently, the M9 sequence was amplified using a primer set, FwdM9 and RevSV40, from p4LambdaN22-3mEGFP-M9 (Reference [4]), it was then digested with BamHI and BglII, and it was then inserted into the BglII site. The sequences of primers and oligonucleotides are shown in the following Tables 1A and 1B.

TABLE 1A Seq ID name sequence(5′ to 3′) No. FwdEGFP CACCGGTCGCCACCATGGGATCCGTGAGCAAGGGC 40 RevEGFP GCCCCGCAGAAGGTCTAGACCTACTTGTACAGCTC 41 GTCCATGCCG FwdtagBFP CACCGGTCGCCACCATGGGATCCAGCGAG 42 RevtagBFP GCCCCGCAGAAGGTCTAGACTATCACTCGAGATGC 43 ATATGAGATC FwdhmAG1 CACCGGTCGCCACCATGGTGAGCGTGATCAAGCCC 44 G RevhmAG1 GCCCCGCAGAAGGTCTAGATTCACTTGGCCTGGCT 45 GGGC FwdhmK02 CACCGGTCGCCACCATGGTGAGTGTGATTAAACCA 46 GAGATG RevhmK02 GCCCCGCAGAAGGTCTAGATTCAGGAATGAGCTAC 47 TGCATCTTCTACCTG FwdhdKeim CACCGGTCGCCACCATGGTGAGCGTGATCGCCAAG 48 aRed RevhdKeim GCCCCGCAGAAGGTCTAGATTCAGCCCAGCAGGCT 49 aRed GTGC RevM9 GCCCCGCAGAAGGTCTAGACTATCACTCGAGATGC 50 ATATGAGATC T7Fwd5UT CAGTGAATTGTAATACGACTCACTATAG 51 R Rev5UTR CATGGTGGCGACCGGTGTCTTATATTTCTTCTTAC 52 TC temp5UTR CAGTGAATTGTAATACGACTCACTATAGGGCGAAT 53 TAAGAGAGAAAAGAAGAGTAAGAAGAAATATAAGA CACCGGTCGCCACCATG Fwd3UTR TCTAGACCTTCTGCGGGGC 54 Rev3UTR TTTTTTTTTTTTTTTTTTTTCCTACTCAGGCTTTA 55 TTCAAAGACCAAG temp3UTR TCTAGACCTTCTGCGGGGCTTGCCTTCTGGCCATG 56 CCCTTCTTCTCTCCCTTGCACCTGTACCTCTTGGT CTTTGAATAAAGCCTGAGTAGG T7FwdA GCTAATACGACTCACTATAGGTCAGATCCGCTAGG 57 ATC T7FwdB GCTAATACGACTCACTATAGGTTCCTTAATCGCGG 58 ATCC Rev120A TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT 59 TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT TTTTTTTTTTTTTTTCCTACTCAGGCTTTATTCA FwdMCS GGGATCCCATGGTGTCGACCTGCAGCATATGAGCT 60 CCTGAATTCGCCCTATAGTGAGTCG RevMCS GGGAGATCTCATATGCATCTCGAGTGATAGTCTAG 61 ACAAGCTTGAGTATTCTATAGTGTCACC Code5UTR AATTAAGAGAGAAAAGAAGAGTAAGAAGAAATATA 62 AGAGCCAC Comp5UTR CATGGTGGCTCTTATATTTCTTCTTACTCTTCTTT 63 TCTCTCTT Code3UTR CTAGACCTTCTGCGGGGCTTGCCTTCTGGCCATGC 64 CCTTCTTCTCTCCCTTGCACCTGTACCTCTTGGTC TTTGAATAAAGCCTGAGTAGGA Comp3UTR AGCTTCCTACTCAGGCTTTATTCAAAGACCAAGAG 65 GTACAGGTGCAAGGGAGAGAAGAAGGGCATGGCCA GAAGGCAAGCCCCGCAGAAGGT

TABLE 1B SEQ ID name sequence(5′ to 3′) No. CFwdtagRF GCCACCATGGGATCCGTGTCTAAGGGCGAAGAGC  66 P CRevtagRF GCTCGAGATCTATTAAGTTTGTGCCCCAGT  67 P CFwdtagBF GCCACCATGGGATCCAGCGAGCTGATTAAGGAGA  68 P AC CRevtagBF ACTCGAGATCTGTGCCCCAGTTTGCTAG  69 P CFwdhmAG GCCACCATGGGATCCGTGAGCGTGATCAAGCCCG  70 1 CRevhmAG TATGAGATCTCTTGGCCTGGCTGGGC  71 1 CFwdhmKO GCCACCATGGGATCCGTGAGTGTGATTAAACCAG  72 2 AGATG CRevhmKO TATGAGATCTGGAATGAGCTACTGCATCTTCTAC  73 2 CTG FwdM9 GAGATCCATGGGATCCAATCAGTCTTCAAATTTT  74 GGAC RevSV40 CTTTATTTGTAACCATTATAAGCTGC  75 Rev120A-2 TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT 212 TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT TTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTTT TTTTTTTTTTTTTTTTTTCCTACTCAGGCTTTAT TCACGCGGC

[Construction of IVT Template DNA]

The protein coding region and control 5′UTR and 3′UTR sequences of the fluorescent protein were amplified according to PCR using suitable primers from plasmids or oligo DNAs. Several 5′UTR fragments were generated from plasmids. The pair of DNA fragments shown in Table 2 was annealed, and was then inserted into the BamHI-AgeI site of 18nt-2xFr15-ECFP (Reference [3]). Subsequently, using a primer set, T7FwdA and Rev5UTR, 5′ UTR was amplified.

TABLE 2 miRNA Primer Sequence name ID name ID hsa-miR-133a MIMAT0000427 5Tmi133a_Afwd/ 182/183 5Tmi133a_Arev hsa-miR-17-3p MIMAT0000071 5Tmi17_3_Afwd/ 184/185 5Tmi17_3_Arev hsa-miR-17-5p MIMAT0000070 5Tmi17_5_Afwd/ 186/187 5Tmi17_5_Arev hsa-miR-1 MIMAT0000416 5Tmi1_Afwd/ 188/189 5Tmi1_Arev hsa-miR-206 MIMAT0000462 5Tmi206_Afwd/ 190/191 5Tmi206_Arev hsa-miR-21-5p MIMAT0000076 5Tmi21_Afwd/ 192/193 5Tmi21_Arev hsa-miR-367-3p MIMAT0000719 5Tmi367_Afwd/ 194/195 5Tmi367_Arev hsa-miR-373-5p MIMAT0000725 5Tmi373_5_Afwd/ 196/197 5Tmi373_5_Arev

TABLE 3 miRNA Primer Sequence name ID name ID hsa-miR-92a-3p MIMAT0000092 5UTR-T92a-3p 198 hsa-miR-16-5p MIMAT0000069 5UTR-T16-5p 199 hsa-miR-197-3p MIMAT0000227 5UTR-T197-3p 200 hsa-miR-24-3p MIMAT0000080 5UTR-T24-3p 201 hsa-miR-339-5p MIMAT0000764 5UTR-T339-5p 202 hsa-miR-224-5p MIMAT0000281 5UTR-T224-5p 203 hsa-miR-127-3p MIMAT0000446 5UTR-T127-3p 204 hsa-miR-365a-3p MIMAT0000710 5UTR-T365a-3p 205 hsa-miR-183-5p MIMAT0000261 5UTR-T183-5p 206 hsa-miR-331-3p MIMAT0000760 5UTR-T331-3p 207 hsa-miR-203a MIMAT0000264 5UTR-T203a 208 hsa-miR-214-3p MIMAT0000271 5UTR-T214-3p 209

TABLE 4 miRNA Primer Sequence name ID name ID hsa-miR-17-5p MIMAT0000070 3UTRtemp_4xT21-5p 210 hsa-miR-21-5p MIMAT0000076 3UTRtemp_4xT17-5p 211

In order to generate an IVT template, a 5′-UTR fragment and a 3′-UTR fragment (10 pmol each) and 50 ng of the protein coding region of a reporter protein were amplified according to PCR using the primer set, T7FwdA and Rev120A, shown in Table 2, and they are then linked to one another. Other 5′-UTR fragments shown in Table 3 were synthesized from oligo DNAs, and the synthesized fragments were then added to second PCR, instead of the 5′ UTR fragment produced in the PCR. In order to prepare control mRNA or a screening library, T7Fwd5UTR or T7FwdB was used instead of T7FwdA in the second PCR. As an IVT template of mRNA comprising 4 copies of miRNA target sequences in the 3′-UTR, the oligo DNA shown in Table 4 was used instead of the PCR fragment of the 3′-UTR, and using Rev120A-2 instead of Rev120A, the fragments were amplified according to PCR and were then linked to one another. The PCR product was purified using MinElute PCR purification kit (QIAGEN) according to the instructions of the manufacturer. Before the purification, the PCR product amplified from the plasmid was digested with Dpn I (Toyobo) at 37° C. for 30 minutes. The sequences of primers are shown in Tables 1A and 1B.

[Synthesis and Generation of mRNA]

The miRNA-responsive reporter mRNA was prepared using MegaScript T7 kit (Ambion) according to modified protocols (see Reference [1] as described below). In this reaction, pseudo uridine-5′-triphosphate and 5-methylcytidine-5′-triphosphate (TriLink BioTechnologies) were used, instead of uridine triphosphate and cytidine triphosphate, respectively. Before the IVT reaction (the synthesis of mRNA), guanosine-5′-triphosphate was 5-fold diluted with Anti Reverse Cap Analog (New England Biolabs). The reaction mixture was incubated at 37° C. for 4 hours, and TURBO DNase (Ambion) was then added to the resultant. Thereafter, the thus obtained mixture was further incubated at 37° C. for 30 minutes. Thereafter, the obtained mRNA was purified with FavorPrep Blood/Cultured Cells total RNA extraction column (Favorgen Biotech), and the resultant was then incubated at 37° C. for 30 minutes, using Antarctic Phosphatase (New England Biolabs). Thereafter, the resultant was further purified using RNeasy MiniElute Cleanup Kit (QIAGEN).

[Screening for miRNA-Responsive mRNA]

Screening for miRNA-responsive mRNA was carried out by three steps. In a first step, miRNA-responsive reporter hmAG1 mRNA and control hmKO2 mRNA were co-introduced, and eight miRNAs, the activities of which largely differed depending on the types of the cells, were selected. In a second step, a combination table of four miRNA-responsive reporter mRNAs was produced, and was then tested. In this combination table, all types of two combinations could be encompassed, such that a pair of any two miRNAs selected from the eight miRNAs could be selected from four types of marker fluorescent proteins. In a third step, four miRNA-responsive reporter mRNAs were newly combined with one another, and several sets were then tested.

[Cell Culture]

HeLa cells and MCF-7 cells were cultured in Dulbecco's modified Eagle's medium (DMEM)-F12 comprising 10% Fetal Bovine Serum (FBS) and 1% Antibiotic Antimycotic Solution (Sigma), and in RPMI 1640, respectively. 293FT cells (Invitrogen) were allowed to grow in DMEM, to which 10% FBS, 2 mM L-Glutamine (Invitrogen), 0.1 mM Non-Essential Amino Acids (Invitrogen), 1 mM Sodium Pyruvate (Sigma) and 0.5% Penicillin-Streptomycin (Invitrogen) had been added. In an experiment in which cells were mixed, individual types of cells were prepared in the same medium as that for the HeLa cells, and the same numbers of cells were mixed with one another and were seeded.

IMR-90 cells (ATCC) were in Eagle's basal medium, to which 10% FBS and 1% Penicillin-Streptomycin-Glutamine (Gibco) had been added, on a gelatin-coated plate. Normal human lung fibroblasts (NHLF; Lonza) were cultured according to the instructions of the manufacturer. IMR-90 within 20 passages and NHLF within 10 passages were used. In order to allow IMR-90 cells to differentiate in vitro, these cells were kept in a starved state in a low-serum medium (0.01% FBS) for 48 hours, and were then stimulated in the low-serum medium in the presence or absence of 10 ng/mL human TGF-β1 (derived from mammals; PeproTech) for 24 hours. Subsequently, the resulting cells were transfected with the above designed and prepared miRNA-responsive reporter mRNA. Four hours after the transfection, the medium was exchanged with the one used in the transfection.

[Transfection with miRNA-Responsive Reporter mRNA]

Cultured cells (HeLa, 293FT, MCF-7, and IMR-90) were seeded on a 24-well plate, and on the following day, the synthesized mRNA was introduced therein. NHLF was seeded on a 24-well plate, and on the same day, the synthesized mRNA was introduced therein. Such introduction was carried out using 1 μL of StemFect (Stemgent) according to the instructions of the manufacturer. For the measurement of translational efficiency, reporter EGFP mRNA responding to each different type of miRNA and control tagRFP (Evrogen) mRNA (each 100 ng) were co-introduced into each cell. However, in an experiment regarding a comparison of the designing of mRNAs (Example 3 and FIG. 6), translational efficiency was distinguished in the presence of 2 pmol mirVana miRNA inhibitor (Applied Biosciences).

In an inhibitor assay, 0.1 to 1 pmol miRNA inhibitor, or 25 to 200 ng of reporter mRNA (comprising a click beetle luciferase CBRluc (Promega) gene in the ORF and having the same 5′-UTR as that of reporter EGFP) was co-introduced, together with two reporter mRNAs. Twenty-four hours after the introduction, the cells were measured by a flow cytometry method using Accuri C6 (BD Biosciences). The fluorescence intensity ratio of two types of reporter proteins in each cell was calculated, and was then plotted. The translational efficiency was distinguished by dividing the average intensity of EGFP responding to miRNA by the average intensity of control tag RFP measured by flow cytometry.

In order to separate cells using two miRNA-responsive reporter mRNAs, 100 ng of reporter mRNA expressing EGFP, and 125 ng of reporter mRNA expressing hmKO2 (Amalgaam) were co-introduced into cells or a mixture thereof. In the first screening for IMR-90 cells, the cells were transfected with 50 ng of reporter hmAG1 (Amalgaam) mRNA and 80 ng of control hmKO2 mRNA. With regard to the differentiated IMR-90 cells and NHLF cells, hmAG1 mRNA and hmKO2 mRNAs were used at 2-fold. In the case of co-introduction of three mRNAs, 40 ng of hmAG1 mRNA, 10 ng of hmKO2 mRNA, and 200 ng of tagBFP (Evrogen) mRNA were used. In the case of co-introduction of four mRNAs, 250 ng of hdKeimaRed (Amalgaam) mRNA was used, as well as the aforementioned three mRNAs. CBG68luc mRNA (SEQ ID NO: 31) was used to dilute hmAG1 mRNA, hmKO2 mRNA, and tagBFP mRNA. The medium was exchanged 4 hours after the transfection.

[Flow Cytometry]

Twenty-hour hours after the transfection, the cells were separated from the culture dish, and they were then passed through a mesh and were analyzed by flow cytometry. For the analysis of co-introduction of two mRNAs, Accuri C6 (BD Biosciences) equipped with FL1 (530/30 nm) and FL2 (585/40 nm) filters was employed. For the analysis of co-introduction of three mRNAs or four mRNAs, FACSAria (BD Biosciences) was employed. hmAG1, hmKO2, tagBFP and hdKeimaRed were detected with blue laser (488 nm) comprising an FITC filter (530/30 nm), and analyzed with green laser (561 nm) comprising PE filter (585/42 nm), violet laser (405 nm) comprising Pacific Blue filter (450/40 nm), and violet laser comprising Qdot 605 filter (610/20 nm), respectively. Dead cells and debris were removed by front and lateral light scattering signals. In the measurement of translational efficiency, the intensity of EGFP and the intensity of tagRFP were corrected based on the spectral matrix obtained from the data set of cells transfected with EGFP or tagRFP (Reference [5]). The translational efficiency was defined as a value obtained by dividing the average intensity of the corrected EGFP signals by the average intensity of the corrected tagRFP signals.

[Imaging Cytometry]

The reporter fluorescent protein was fused with the nuclear localization signal M9 on the C-terminal side, so that the co-introduced cells were clarified. Twenty-four hours after introduction of three mRNAs, using IN Cell Analyzer 6000 (GE Healthcare), the bright field image and fluorescence image of the cells were obtained. The fluorescence signals of hmAG1, hmKO2 and tagBFP were measured using blue laser comprising an FITC filter, green laser comprising a DsRed filter, and UV laser comprising a DAPI filter, respectively. The obtained images were analyzed using Cell Profiler (Reference [2]). First, the nucleus was identified in the average images of three fluorescence channels. Subsequently, as with flow cytometry, the hmKO2 signals and the tagBFP signals were divided by the hmAG1 signals in every pixel. Then, the geometric mean rate in each nucleus was obtained. The images were edited using ImageJ (manufactured by The National Institutes of Health (NIH)).

Example 1: One-Dimensional Separation of Existing Cell Lines, Using miRNA-Responsive Reporter mRNA

One-dimensional separation of existing cell lines was carried out using one or two types of miRNA-responsive reporter mRNAs. The results are shown in FIGS. 3A to 3H. FIG. 3A is a schematic view showing in vitro synthesized miRNA-responsive reporter mRNA used in the present Example. In the direction from the 5′-terminus on the left side to the 3′-terminus on the right side on the paper, ARCA (gap structure analog), a miRNA target sequence, a gene encoding a fluorescent protein, and poly(A) tail are positioned. The ARCA, the miRNA target sequence, and the initiation codon were designed, such that the ARCA could be separated from the miRNA target sequence by approximately 20 nucleotides, and the miRNA target sequence could also be separated from the initiation codon by approximately 20 nucleotides.

FIG. 3B is a graph showing a comparison in translational efficiency, when three types of miRNA-responsive reporter mRNAs were each introduced into three types of cell lines. A gene encoding EGFP was used as a marker gene in all cases, and miR-21-5p, miR-24-3p and miR-203a were used as miRNA target sequences, respectively. With regard to the three types of miRNA-responsive reporter mRNAs (α(miR-21-5p)-EGFP (SEQ ID NO: 1), α(miR-24-3p)-EGFP (SEQ ID NO: 3), and α(miR-203a)-EGFP (SEQ ID NO: 5)), 100 ng of each mRNA, together with 100 ng of control tagRFP mRNA (SEQ ID NO: 24), was directly co-introduced into HeLa, 293FT and MCF-7 cells. Translational efficiency was distinguished by dividing the average intensity of EGFP by the average intensity of tagRFP according to a flow cytometric measurement 24 hours after the co-introduction. The numerical value in the upper portion of each graph column indicates the magnification of translational efficiency among the individual cell lines. The error bar indicates an average±standard deviation (n=3).

FIG. 3C is a dot plot showing the measurement results obtained 24 hours after the co-introduction of miR-21-5p-responsive EGFP mRNA and control hmKO2 mRNA (SEQ ID NO: 22) into each of HeLa cells and 293FT cells. On the other hand, FIG. 3F, is a dot plot showing the measurement results obtained 24 hours after the co-introduction of the same mRNAs as those described above into a mixture of HeLa cells and 293FT cells. The measurement was carried out using Accuri C6 flow cytometer, and the test was independently performed three times. Representative results were shown in the figure. From the fluorescence intensity ratio reflecting a difference in miRNA activity, it is found that the two types of cell lines were apparently separated from each other.

FIG. 3D is a dot plot showing the measurement results obtained 24 hours after the co-introduction of miR-24-3p-responsive EGFP mRNA and miR-203a-responsive hmKO2 mRNA (SEQ ID NO: 6) into each of HeLa cells and MFC-7 cells. On the other hand, FIG. 3H is a dot plot showing the measurement results obtained 24 hours after the co-introduction of the same mRNAs as those described above into a mixture of HeLa cells and MFC-7 cells. Referring to FIG. 3B, it is found that the activities of these miRNAs were slightly and reversely different in the two cell lines. Referring to FIGS. 3D and 3H, it is found that the two types of cell lines were clearly separated from each other, using such a slight difference in the activity.

FIG. 3E includes histograms showing the ratio of two fluorescence signals. A set of miRNA-responsive reporter mRNA/control mRNA (EGFP mRNA (SEQ ID NO: 19) or hmKO2 mRNA (SEQ ID NO: 22)) shown in each histogram was co-introduced into HeLa cells, MCF-7 cells, and a mixture thereof. The cumulative frequency of the fluorescence ratio of cells, into which the two types of miRNA-responsive reporter mRNAs have been introduced, is shown in the lowest column. In addition, FIG. 3G includes histograms showing the ratio of two fluorescence signals in the dot plot shown in each of FIG. 3C and FIG. 3F.

Example 2: Cell Separation in a Higher-Dimensional Space

Cell separation was carried out using three types of or four types of miRNA-responsive reporter mRNAs. First, three types of miRNA-responsive reporter mRNAs, α(miR-24-3p)-EGFP, α(miR-127-3p)-EGFP (SEQ ID NO: 7), α(miR-17-5p)-EGFP (SEQ ID NO: 9) and α(miR-92a-3p)-EGFP (SEQ ID NO: 15), were measured in terms of translational efficiency in HeLa, 293FT, and MCF-7 cells. The results are shown in FIG. 4, panels (a) and (d). The numerical value at the top of each column indicates the translational efficiency ratio of two types out of the three types of cell lines. The error bars each indicate a mean value±standard deviation (n=3).

The results obtained by performing two-dimensional separation using three types of miRNA-responsive reporter mRNAs (α(miR-24-3p)-hmAG1 (SEQ ID NO: 4), α(miR-127-3p)-hmKO2 (SEQ ID NO: 8) and α(miR-17-5p)-tagBFP (SEQ ID NO: 13)) are shown in FIG. 4, panel (b). Three types of miRNA-responsive reporter mRNAs were each independently co-introduced into three types of cell lines, and twenty-four hours later, the results were analyzed by FACSAria. The data of flow cytometry were plotted regarding two ratios. The two ratios indicate a value obtained by dividing the hmKO2 intensity by the hmAG1 intensity, and a value obtained by dividing the tagBFP intensity by the hmAG1 intensity. The densities of the HeLa cells, 293FT cells and MCF-7 cells, which involved co-introduction of the mRNAs, were plotted on the plane. With regard to the colored density plots, the densities of 293FT cells, HeLa cells and MCF-7 cells were indicated with red, green and blue channels, respectively, and the obtained images were then overlapped, and the colored density plots were produced as negative images thereof.

The results obtained by performing two-dimensional separation on a sample prepared by mixing three types of cells, using three types of miRNA-responsive reporter mRNAs, are shown in FIG. 4, panel (c). The data of flow cytometry were plotted regarding two ratios.

Three-dimensional separation was carried out using four types of miRNA-responsive reporter mRNAs. Four types of control mRNAs, hmAG1 mRNA (SEQ ID NO: 21), hmKO2 mRNA (SEQ ID NO: 22), tagBFP mRNA (SEQ ID NO: 20) and hdKeimaRed mRNA (SEQ ID NO: 23), were co-introduced into each of HeLa, 293FT, MCF-7, and a mixture thereof. On the other hand, four types of miRNA-responsive reporter mRNAs, α(miR-24-3p)-hmAG1, α(miR-127-3p)-hmKO2, α(miR-92-3p)-tagBFP (SEQ ID NO: 17) and α(miR-17-5p)-hdKeimaRed (SEQ ID NO: 14), were co-introduced into each of HeLa, 293FT, MCF-7, and a mixture thereof. Twenty-four hours after the introduction, a flow cytometric analysis was carried out. The results obtained by performing three-dimensional separation using four types of miRNA-responsive reporter mRNAs are shown in FIG. 4, panel (e). After completion of the measurement by flow cytometry, geometric means of three ratios, that is, a value obtained by dividing the hmKO2 intensity by the hmAG1 intensity, a value obtained by dividing the tagBFP intensity by the hmAG1 intensity, and a value obtained by dividing the hdKeimaRed intensity by the hmAG1 intensity were calculated and were then plotted. The error bar indicates a geometric mean±geometric standard deviation in each axis (n=5900 to 7300).

The cell density was plotted on three planes vertical to three axes, and the fluorescence intensities of hmKO2, tagBFP and hdKeimaRed were each divided by the fluorescence intensity of hmAG1. The density plot is shown in FIGS. 5A to 5D. FIGS. 5A to 5D shows representative results obtained from three independent experiments. From FIG. 5A, it is found that, even referring to any plane plot, the three types of cell lines, into which the four types of control mRNAs had been co-introduced, could not be separated from one another. On the other hand, from FIG. 5C, it is found that the three types of cell lines, into which the four types of miRNA-responsive reporter mRNAs had been co-introduced, could be apparently separated from one another in all of the planar dot plots. Moreover, from FIG. 5D, cell separation can also be confirmed in a mixture of the three types of cell lines by visual observation. That is to say, it becomes possible to perform determination capable of separating a mixture of cell lines into three types of cell lines.

Control mRNAs having no miRNA target sequences, namely, hmAG1 mRNA, hmKO2 mRNA, and tagBFP mRNA were each diluted to 5 stages of dilutions by 2-fold, and these dilutions were then combined in various ways and were then co-introduced into HeLa cells. Density plots obtained from 46 types of independent introduction results are shown in FIG. 4, panel (f). Set A is a group comprising dot plots obtained from 4 stages of 2-fold dilutions, and Set B is a group comprising dot plots obtained from 5 stages of 2-fold dilutions. Detailed introduction conditions are shown in Table 5A and Table 5B. This experiment, in which a plurality of control mRNAs were diluted to various concentrations, demonstrates various miRNA-responsive reporter mRNAs that may be generated by miRNA activity in cells. That is, it is suggested that, theoretically, focusing on three types of miRNAs, when the activity of each miRNA is assumed to be different with 4 stages by 2-fold (wherein at maximum 43=64 cell types can be assumed), the cells can be separated into at maximum 37 types by using three types of miRNA-responsive reporter mRNAs. In addition, it is also suggested that cells can be separated by the same method as that described above, even in a case in which the activity of miRNA is different with 5 stages (by 2-fold) (in such a case, at maximum 53=125 cell types can be assumed, and the cells can be separated into at maximum 61 types using three types of miRNA-responsive reporter mRNAs).

TABLE 5A Dilution factor hmAG1 hmKO2 tagBFP hmKO2/hmAG1 tagBFP/hmAG1 Set (40 ng) (10 ng) (200 ng) mean 90% interval mean 90% interval A 1 1 1 1.574 2.245 2.965 1.973 A 1 1 2 1.442 2.280 1.401 2.008 A 1 1 4 1.660 2.593 0.787 1.975 A 1 1 8 1.603 2.377 0.383 1.937 A 1 2 1 0.929 1.940 2.806 1.886 A 1 2 2 0.878 2.426 1.386 1.953 A 1 2 4 0.952 2.304 0.753 2.007 A 1 2 8 0.897 2.235 0.365 1.987 A 1 4 1 0.472 2.787 2.825 2.047 A 1 4 2 0.469 2.382 1.447 2.057 A 1 4 4 0.517 2.737 0.793 1.966 A 1 4 8 0.459 2.197 0.341 1.995 A 1 8 1 0.277 2.710 2.968 1.971 A 1 8 2 0.298 3.082 1.545 2.088 A 1 8 4 0.272 3.230 0.710 2.019 A 1 8 8 0.284 3.086 0.389 2.045 A 1 1 1 9.564 2.687 15.421 2.587 A 1 1 2 9.031 2.431 7.598 2.502 A 1 1 4 10.309 2.433 4.166 2.415 A 1 1 8 9.847 2.328 2.012 2.268 A 8 2 1 6.004 2.009 15.804 3.018 A 8 2 2 5.903 2.027 7.718 3.157 A 8 2 4 5.581 2.071 3.819 2.898 A 8 2 8 5.832 2.078 2.093 2.396 A 8 4 1 3.380 2.131 15.611 3.558 A 8 4 2 3.166 1.987 8.567 2.789 A 8 4 4 3.244 2.051 4.150 2.758 A 8 4 8 3.219 1.951 2.196 2.360 A 8 8 1 1.709 2.336 16.277 2.502 A 8 8 2 1.648 2.164 8.270 2.441 A 8 8 4 1.720 2.145 4.311 2.393 A 8 8 8 1.881 2.247 2.196 2.532 A 2 1 8 2.897 1.663 0.614 2.026 A 2 8 1 0.543 2.981 4.638 2.142

TABLE 5B Dilution factor hmAG1 hmKO2 tagBFP hmKO2/hmAG1 tagBFP/hmAG1 Set (40 ng) (10 ng) (200 ng) mean 90% interval mean 90% interval A 4 1 8 5.279 1.723 1.092 2.057 A 4 2 8 3.291 1.736 1.203 2.139 A 4 8 1 1.020 2.603 9.637 2.382 A 4 8 2 0.992 2.511 4.675 2.360 B 1 1 16 1.742 1.657 0.199 2.062 B 1 16 1 0.193 5.100 2.857 2.129 B 1 16 16 0.203 4.997 0.219 2.162 B 16 1 16 16.047 2.784 1.610 2.336 B 16 16 1 2.006 2.553 29.087 4.669 B 16 1 1 15.916 2.640 25.754 3.660 B 4 16 1 0.636 4.540 8.858 2.585 B 4 1 16 5.799 1.675 0.631 2.042 *mean: geometric mean *90% interval: fold-change

Example 3: Insertion of miRNA Target Sequence and Translational Efficiency

The position of a miRNA target sequence in reporter miRNA-responsive reporter mRNA was examined. That is, miRNA-responsive reporter mRNA (α(miR-21-5p)-EGFP (SEQ ID NO: 1)) in which one perfect complementary sequence of miR-21-5p that is the target site of miR-21-5p is present in the 5′UTR, and miRNA-responsive reporter mRNA (EGFP-4xα(4xmiR-21-5p) (SEQ ID NO: 2)) in which four perfect complementary sequences of miR-21-5p are present in the 3′UTR, were prepared. The thus prepared mRNAs were examined in terms of translational efficiency. Likewise, miRNA-responsive reporter mRNA (α(miR-17-5p)-EGFP (SEQ ID NO: 9)) in which one perfect complementary sequence of miR-17-5p that is the target site of miR17-5p is present in the 5′UTR, and miRNA-responsive reporter mRNA (EGFP-4xα(4xmiR-17-5p) (SEQ ID NO: 10)) in which four perfect complementary sequences of miR-17-5p are present in the 3′UTR, were prepared. The thus prepared mRNAs were examined in terms of translational efficiency. The translational efficiency of each reporter mRNA was measured in the presence of an inhibiting agent (inhibitor) to miRNA, to which the reporter mRNA responded. An inhibitor to miR-1 was used as a negative control. The concentration of such an inhibitor was set at 2 pmol. The error bars each indicate a mean value±standard deviation (n=2). The results are shown in FIG. 6.

Example 4: Activity of miRNA-Responsive Reporter mRNA as miRNA Inhibitor

An experiment was carried out to verify a difference between a commercially available miRNA inhibitor and miRNA-responsive reporter mRNA. The translational efficiency of α(miR-17-5p)-EGFP responding to the same miR-17-5p in HeLa cells was measured in the presence of a commercially available miRNA inhibitor or miR-17-5p-responsive reporter mRNA (α(miR-17-5p)-CBRLuc (SEQ ID NO: 33); it does not exhibit fluorescence because it is a luciferase gene). An inhibitor to miR-1 and luciferase mRNA (α(miR-1)-CBRLuc (SEQ ID NO: 32)) responding to miR-1 were used as negative controls. The results are shown in FIG. 7, panel (a). The error bars each indicate a mean value±standard deviation (n=3). From these results, it is found that miRNA-responsive reporter mRNA hardly functions as a miRNA inhibitor.

It was confirmed that reporter mRNAs (luciferase) responding to six other types of miRNAs (that is, α(miR-21-5p)-CBRluc: SEQ ID NO: 34, α(miR-92a-3p)-CBRluc: SEQ ID NO: 35, α(miR-24-3p)-CBRluc: SEQ ID NO: 36, α(miR-127b-3p)-CBRluc: SEQ ID NO: 37, α(miR-16-5p)-CBRluc: SEQ ID NO: 38, and α(miR-203a)-CBRluc: SEQ ID NO: 39) do not function as miRNA inhibitors.

The activity of each miRNA was measured using EGFP reporter mRNA responding to the miRNA. At this time, miR-1 (negative control) or luciferase reporter mRNA responding to the same miRNA was introduced. The results obtained from testing 3 times are shown in FIG. 7, panel (b).

Example 5: Translational Efficiency of miRNA-Responsive Reporter mRNA in Three Types of Cell Lines

Twenty types of miRNA-responsive reporter mRNAs were introduced into each of three types of cell lines, and the translational efficiency ratio was then examined. FIG. 8 includes graphs showing the translational efficiency of these 20 types of miRNA-responsive reporter mRNAs in the three types of cell lines. FIG. 8, panel (a) shows a comparison made between HeLa and 293FT, FIG. 8, panel (b) shows a comparison made between 293FT and MCF-7, and FIG. 8, panel (c) shows a comparison made between MCF-7 and HeLa. The error bars each indicate a mean value±standard deviation (n=3). Using the value of translational efficiency obtained from the present results, a vector was configured with this value. In this case, the distance between cells in the possible coordinate was calculated, and a combination of miRNA-responsive reporter mRNAs used in other Examples was selected.

Example 6: One-Dimensional Separation Using Two Types of miRNA-Responsive Reporter mRNAs

One dimensional separation of cells was carried out using two types of miRNA-responsive reporter mRNAs, based on the fluorescence intensity ratio of two types of cell lines, in the same manner as that of Example 1. A series of results is shown in FIGS. 9A to 9H. The results show that, even in two types of cell lines, in which the transcriptional efficiency of certain miRNA-responsive reporter mRNA, that is, the miRNA activity was 2-fold or less, 293FT could be separated from HeLa, or 293FT could be separated from MCF-7. The error bars each indicate a mean value±standard deviation (n=3).

In order to examine the activities of miR-24-3p and miR-17-5p in 293FT cells and HeLa cells, translational efficiency was measured. For the measurement, α(miR-24-3p)-EGFP and α(miR-17-5p)-EGFP were used. The results are shown in FIG. 9A. The numerical value at the top of each column indicates the ratio of translational efficiency. Into 293FT cells, HeLa cells and a mixture thereof, α(miR-24-3p)-EGFP and α(miR-17-5p)-hmKO2 (SEQ ID NO: 12) were co-introduced, and 24 hours after the introduction, a flow cytometric analysis was carried out. As control mRNAs, EGFP and hmKO2 were used. FIG. 9B shows the results of dot plotting. From the figure, it is found that the 293FT cells could be distinguished from the HeLa cells as different belt-shaped plots. Moreover, FIG. 9G shows the same dot plotting as that described above, regarding a mixture of 293FT and HeLa. From these results, it is found that the two types of cells could be observed separately, even if a mixture of these cells was measured. FIG. 9C shows histograms regarding signal ratio. A set of miRNA-responsive reporter mRNA/control mRNA, as shown in each histogram, was co-introduced into each cell line. The ratio of two types of fluorescence signals, which had been measured by flow cytometry, was calculated, and was then plotted. The cumulative frequency of cells, into which two types of miRNA-responsive reporter mRNAs were introduced, is shown in the lowest column of FIG. 9C.

Likewise, in order to examine the activities of miR-17-5p and miR-127-3p in 293FT cells and MCF-7 cells, translational efficiency was measured. For the measurement, α(miR-17-5p)-EGFP and α(miR-127-3p)-EGFP were used. The results are shown in FIG. 9D. The numerical value at the top of each column indicates the ratio of translational efficiency. Into 293FT cells, MCF-7 cells and a mixture thereof, α(miR-17-5p)-EGFP and α(miR-127-3p)-hmKO2 were co-introduced, and 24 hours after the introduction, a flow cytometric analysis was carried out. As control mRNAs, EGFP and hmKO2 were used. FIG. 9E shows the results of dot plotting. It is found that the 293FT cells could be distinguished from the MCF-7 cells as different belt-shaped plots. Moreover, FIG. 9H shows the same dot plotting as that described above, regarding a mixture of 293FT and MCF-7. From these results, it is found that the two types of cells could be observed separately, even if a mixture of these cells was measured. FIG. 9F shows histograms regarding signal ratio. A set of miRNA-responsive reporter mRNA/control mRNA, as shown in each histogram, was co-introduced into each cell line. The ratio of two types of fluorescence signals, which had been measured by flow cytometry, was calculated, and was then plotted. The cumulative frequency of cells, into which two types of miRNA-responsive reporter mRNAs were introduced, is shown in the lowest column of FIG. 9F.

Example 7: Co-Introduction of Three Types of miRNA-Responsive Reporter mRNAs, in which Reporter Fluorescent Protein is Linked to Nuclear Localization Signal

Into HeLa, 293FT and MCF-7 cells, three types of miRNA-responsive reporter mRNAs expressing nuclear localized fluorescent proteins, namely, 40 ng of α(miR-24-3p)-hmAG1-M9 (SEQ ID NO: 25), 10 ng of α(miR-127-3p)-hmKO2-M9 (SEQ ID NO: 26), and 200 ng of α(miR-17-5p)-tagBFP-M9 (SEQ ID NO: 27) were co-introduced. Twenty-four hours after the introduction, an imaging cytometric analysis was carried out. FIG. 10, panel (a) shows the fluorescence images of the introduced cells. In the figure, . . . indicates 100 μm. The hmKO2, hmAG1, and tagBFP were indicated with red, green and blue channels, respectively. From FIG. 10, panel (a), it is found that there is a variation in intensity, depending on the nucleus. FIG. 10, panel (b) shows the results obtained by subjecting the measured data of the same target as that in FIG. 10, panel (a) to pseudo-color processing using two ratios. The nucleus was removed from the cells involving co-introduction, and fluorescence intensity in each pixel was then analyzed. The ratio obtained by dividing the fluorescence signals of hmKO2 by the fluorescence signals of hmAG1, and the ratio obtained by dividing the fluorescence signals of tagBFP by the fluorescence signals of hmAG1, were normalized from the ranges of 10-0.25 to 100.75 and 10-0.5 to 100.5, to result in 0 to 1, respectively, and the ratios were then indicated with violet color and green color, respectively. FIG. 10, panel (c) shows the density plotting of these ratios.

Example 8: Two-Dimensional Separation by Flow Cytometry and Imaging Cytometry, Using Three Types of miRNA-Responsive Reporter mRNAs

Into each of HeLa, 293FT, MCF-7, and a mixture thereof, three types of control mRNAs, hmAG1, hmKO2 and tagBFP were co-introduced. In addition, into HeLa, 293FT, MCF-7, and a mixture thereof, three types of control mRNAs, in which a reporter fluorescent protein was linked to a nuclear localization signal, namely, hmAG1-M9 (SEQ ID NO: 28), hmKO2-M9 (SEQ ID NO: 29) and tagBFP-M9 (SEQ ID NO: 30) were co-introduced. Likewise, into each of HeLa, 293FT, MCF-7, and a mixture thereof, three types of miRNA-responsive reporter mRNAs, α(miR-24-3p)-hmAG1, α(miR-127-3p)-hmKO2 and α(miR-92-3p)-tagBFP were co-introduced. Also, into each of HeLa, 293FT, MCF-7, and a mixture thereof, three types of miRNA-responsive reporter mRNAs, in which a reporter fluorescent protein was linked to a nuclear localization signal, that is, α(miR-24-3p)-hmAG1-M9, α(miR-127-3p)-hmKO2-M9 and α(miR-92-3p)-tagBFP-M9 were co-introduced. Twenty-four hours after these introductions, a flow cytometric analysis and an imaging cytometric analysis were carried out. Representative results obtained from three independent experiments are shown in FIGS. 11A to 11H.

The flow cytometric analysis results of HeLa cells, 293FT cells, MCF-7 cells, and a mixture thereof, into which the three types of control mRNAs were introduced, are shown in FIG. 11A, and the imaging cytometry results thereof are shown in FIG. 11C. Moreover, the flow cytometric analysis results of HeLa cells, 293FT cells, MCF-7 cells, and a mixture thereof, into which the three types of control mRNAs, in which a reporter fluorescent protein was linked to a nuclear localization signal, were co-introduced, are shown in FIG. 11E, and the imaging cytometry results thereof are shown in FIG. 11G. From all of these results, it is found that cells could not be separated from one another.

The flow cytometric analysis results of HeLa cells, 293FT cells, MCF-7 cells, and a mixture thereof, into which the three types of miRNA-responsive reporter mRNAs were introduced, are shown in FIG. 11B, and the imaging cytometry results thereof are shown in FIG. 11D. Moreover, the flow cytometric analysis results of HeLa cells, 293FT cells, MCF-7 cells, and a mixture thereof, into which the three types of miRNA-responsive reporter mRNAs, in which a reporter fluorescent protein was linked to a nuclear localization signal, were co-introduced, are shown in FIG. 11F, and the imaging cytometry results thereof are shown in FIG. 11H. When the three types of miRNA-responsive reporter mRNAs were introduced into the three types of cells, the cells could be separated from one another, either by flow cytometry or by imaging cytometry. Since an independent plot group could be observed even in a mixture of cells, it is found that it is possible to separate the three types of cells from one another. Furthermore, even in a case in which the three types of miRNA-responsive reporter mRNAs, in which a reporter fluorescent protein was linked to a nuclear localization signal, were used, the same results as those described above were obtained.

Example 9: Separation of Fibroblast Lines Using miRNA-Responsive Reporter mRNA

An experiment was carried out to distinguish not only cell lines from different origins, but also differences in conditions of identical cell lines. Herein, IMR-90 cells were focused on as representative normal human cells. It has been known that IMR-90, which is in a resting state, tends to differentiate to smooth muscle by receiving TGF stimulation. Sixty-seven types of miRNAs, which had been confirmed to be expressed in IMR-90 and do not comprise CAU, were selected, and a library of miRNA-responsive reporter mRNAs expressing hmAG1 as a reporter protein was then produced (SEQ ID NOS: 77 to 143). Each mRNA, together with control hmKO2 mRNA, was introduced into IMR-90, and a flow cytometric analysis was then carried out.

Subsequently, a first screening was carried out, and 26 miRNA-responsive mRNAs, which were active in IMR-90, were obtained. The results are shown in FIG. 12A. In FIG. 12A, mRNAs having an average fluorescence ratio (FL2/FL1) of 0.199 or more were distinguished to have activity (whereas in the case of mRNA that does not respond to control miRNA, it is 0.198). From the 26 miRNAs, two types of mRNAs having high similarity to each other were omitted, and the remaining 24 miRNA-responsive mRNAs were extracted.

Further, miRNA-responsive reporter mRNAs responding to two miRNAs highly associated with muscle differentiation were produced (SEQ ID NOS: 144 and 145). To these two mRNAs, the above extracted 24 mRNAs, and 6 mRNAs, the activity of which was not observed in the above section and which responded to miRNA associated with TGF signals or muscle differentiation, were gathered, and a total of 32 mRNAs were subjected to a second screening for searching for miRNA, the activity of which was changed before and after TGF-β1 stimulation to IMR-90. IMR-90 was left in a starved state for 2 days, and was then stimulated with 10 ng/mL TGF-β1. On the following day, mRNA was introduced into the cells, and further, on the day following the introduction, a flow cytometric analysis was carried out. The results obtained by searching for the total of 32 types of miRNAs are shown in FIG. 12B. The miRNA-responsive mRNA (α(miR-145-5p)-hmAG1) (SEQ ID NO: 117), which had the highest activity in FIG. 12B was used in the subsequent experiment.

Imaging cytometry was carried out as follows. IMR-90, with or without TGF stimulation, was simultaneously stained with miRNA-responsive mRNA (a pair of α(miR-145-5p)-hmAG1 and hmKO2) and an anti-aSMA antibody.

Differentiation induction and the immunostaining of IMR-90 after introduction of mRNA were carried out by the following methods. One day after the co-introduction of mRNA, a medium and Cytofix Fixation Buffer (BD Biosciences) in an amount equal to the medium were added to the cells, followed by leaving them to rest at 37° C. for 10 minutes, so that the cells were immobilized. Subsequently, the resulting cells were washed with Pharmingen Stain Buffer (FBS, BD Biosciences), and were then left to rest in Phosflow Perm Buffer III (BD Biosciences) on ice for 30 minutes, so that the permeation treatment of the cell membrane was carried out. After washing, the resulting cells were left to rest in Blocking One (Nakalai Tesque, Inc.) on ice for 30 minutes. Thereafter, the cells were stained with an anti-aSMA antibody, which had been 200-fold diluted with Pharmingen Stain Buffer (FBS) comprising 10% Blocking One, at room temperature for 30 minutes. After washing, the resulting cells were stained with Hoechist 33342 (Life Technologies). The thus-stained cells were analyzed using IN Cell Analyzer 6000.

Flow cytometry on intracellular factors was carried out as follows. After completion of differentiation induction and introduction of mRNA, IMR-90 was peeled from the culture plate. The cells were immobilized and were then subjected to membrane permeation, using the aforementioned Cytofix Fixation Buffer and Phosflow Perm Buffer III, according to the instruction manual.

After completion of the membrane permeation, the cells were blocked with Blocking One, and were then stained with a 100-fold diluted anti-aSMA antibody at room temperature for 30 minutes, in the same manner as that described above. After completion of the staining, the cells were washed and were then subjected to a flow cytometric analysis.

The results of the flow cytometric analysis are shown in FIG. 12C in the form of a density plot. From the results shown in FIG. 12C, a difference in the differentiation conditions of the cells of the same type could be distinguished, by using α(145-5p)-hmAG1. FIG. 12D shows the same experimental results as those described above in the form of histograms. Herein, the results obtained by introduction of a pair of control mRNAs are shown with the solid line and the dashed line. In the case of applying an antibody staining method of the prior art, cells need to be immobilized, and as shown in the histograms, the width of distribution was wide and there were many overlapping portions. On the other hand, in the case of applying the method of the present invention, it was demonstrated that living cells can be directly used, and thus, that the width of distribution is narrow and sufficient determination can be carried out.

A similar experiment was carried out using a nuclear localized reporter protein, and imaging cytometry was then carried out. The results are shown in FIG. 12F. Herein, an image analysis was carried out, the fluorescence ratio (hmKO2/hmAG1) per pixel was then calculated, and it was then indicated in green in the picture. The fluorescence intensity from the antibody was indicated in magenta. The same experimental results as those described above are shown in FIG. 12E in the form of histograms. Herein also, the results obtained by introduction of a pair of control mRNAs are shown with the solid line and the dashed line.

The results shown in FIG. 12E and FIG. 12F demonstrated that when the mRNA of the present invention is used, the quantitative ratio of a nuclear localized protein is different between the case of the presence of TGF-β1 stimulation and the case of the absence of such stimulation. It was also found that these results are highly matched with the results obtained by the flow cytometric analysis shown in FIG. 12D.

Moreover, the combination of the reporter proteins of miRNA-responsive mRNAs was changed, and the same analysis as that described above was carried out using a pair of α(miR-145-5p)-hmKO2 and hmAG1. The results of imaging cytometry are shown in FIG. 17A, and the results of flow cytometry are shown in FIG. 17B. As a result, it was confirmed that the expression of miR-145-5p in SMA-positive cells is increased by muscle differentiation with the addition of TGF-β1, as in the case of using the aforementioned pair of α(miR-145-5p)-hmAG1 and hmKO2, and that the expression of the corresponding reporter protein is decreased.

As described above, it was demonstrated that the present invention is able to discriminate living cells, not depending on the type of a reporter protein.

Example 10: Discrimination of Cell Population of Primary Culture (NHLF), Using miRNA-Responsive Reporter mRNA

Using the same library of 67 miRNAs as described above, not the miRNA activity of the established cells, but the miRNA activity of a population of the primary cultured cells (NHLF) of human normal lung fibroblasts was examined. FIG. 13, panel (a) shows the strategy of searching for mRNA for selecting cells (for clarifying the mixing state of cells). In a first screening, the activity of miRNA was detected, and 8 miRNAs were selected from the 67 miRNAs. In a second screening, the 8 miRNAs were combined with reporter proteins, and 56 sets of reporter mRNAs were searched.

Using the same library of 67 types of miRNA-responsive reporter mRNAs as that for IMR-90, the activity of miRNA in the primary cultured cells (NHLF) of human normal lung fibroblasts was searched. The results are shown in FIG. 13, panel (b). Herein, in particular, the peak width (90% interval) of the fluorescence ratio created by cell populations, into which mRNA had been introduced, was analyzed, and 8 miRNAs having a large peak width (i.e. miR-16-5p, miR-17-5p, miR-21-5p, miR-27a-3p, miR-20a-5p, miR-106a-5p, miR-143-3p, and let-7i-5p) were selected.

FIG. 14, panels (a) and (b) show the results obtained by comparing the results of the first screening between the cell line (IMR-90) and the primary cultured cells (NHLF). FIG. 14, panels (a) and (b) both show the results regarding the 67 types of miRNA-responsive reporter mRNAs. That is, FIG. 14, panel (a) shows the comparison of fluorescence ratio, that is, the comparison of peak position, whereas FIG. 14, panel (b) shows the comparison of 90% interval, that is, the comparison of peak width. In both of the figures, a mean value from screening experiments conducted twice and a standard deviation are indicated as an error bar. From FIG. 14, panels (a) and (b), it was demonstrated that the mean value of miRNA activity was the same as that of the established IMR-90, but that the miRNA activity was distributed more broadly in the cell population, and thus, it was a more heterogeneous population.

FIG. 13, panel (c) shows a combination table used for a second screening. The numbers 1 to 8 indicate 8 types of miRNAs, and in this experiment, the numbers 1 to 8 successively indicate miR-16-5p, miR-17-5p, miR-21-5p, miR-27a-3p, miR-20a-5p, miR-106a-5p, miR-143-3p, and let-7i-5p. In the table, the row (h), the column (i), and two-digit numbers (j, k) in each square indicate miRNA numbers, to which hmAG1, hmKO2, tagBFP, and hdKeimaRed respond, respectively. According to this table, it is found that all combinations of reporter proteins can be encompassed regarding a combination of any two miRNAs.

Subsequently, the correlation of these miRNA activities was obtained. Regarding each combination of miRNAs, a pair of reporter mRNAs responding to the miRNAs (SEQ ID NOS: 114, 81, 115, 102, 80, 111, 83, 116, and 157 to 181) was introduced into NHLF, and the peak width (90% interval) of the fluorescence ratio created by the cell population was then analyzed. A mean value of the values obtained from the following 6 types of combinations was obtained. For example, in the case of miR-143-3p and miR-21-5p, the combinations are as follows:

(A) α(miR-143-3p)-hmAG1 (SEQ ID NO: 114)+α(miR-21-5p)-hmKO2 (SEQ ID NO: 159), (B) α(miR-143-3p)-hmAG1+α(miR-21-5p)-tagBFP (SEQ ID NO: 168), (C) α(miR-143-3p)-hmAG1+α(miR-21-5p)-hdKeimaRed (SEQ ID NO: 176), (D) α(miR-21-5p)-hmAG1 (SEQ ID NO: 81)+α(miR-143-3p)-hmKO2 (SEQ ID NO: 163), (E) α(miR-21-5p)-hmAG1+α(miR-143-3p)-tagBFP (SEQ ID NO: 172), and (F) α(miR-21-5p)-hmAG1+α(miR-143-3p)-hdKeimaRed (SEQ ID NO: 180).

This peak width is shown in the following Table 6 as a relative value to the peak width obtained by the same analysis when control mRNA has been introduced into cells.

TABLE 6 relative 90% interval miR-143-3p miR-21-5p let-7i-5p miR-27a-3p miR-16-5p miR-20a-5p miR-17-5p miR-106a-5p miR-143-3p 2.77 1.90 1.87 2.17 2.32 2.22 2.34 miR-21-5p 1.38 1.43 1.53 1.59 1.84 1.76 let-7i-5p 1.12 1.24 1.42 1.49 1.52 miR-27a-3p 1.18 1.41 1.37 1.43 miR-16-5p 1.19 1.21 1.18 miR-20a-5p 0.96 0.91 miR-17-5p 0.97 miR-106a-5p

From this Table, it is found that a functional relationship can be found between miRNAs in the target cell population. For example, there is a negative correlation between the functions of miRNA having large values, such as a combination of miR-143-3p and miR-21-5p. That is, in this case, the activity of miR-21-5p is low in cells in which the activity of miR-143-3p is high, and the activity of miR-21-5p is low in cells in which the activity of miR-143-3p is low. On the other hand, there is a positive correlation between the functions of miRNAs having small values. It was demonstrated that, in fact, miR-17, miR-20a and miR-106a, which form a miR-17 precursor family, exhibit a high positive correlation in terms of activity.

The reason the relationship in terms of miRNA activity is clarified will be described using FIG. 15. FIG. 15 is a view schematically showing assumed results obtained when a certain cell group has incorporated equal amounts of mRNAs and there is a distribution of two miRNA activities in the cell group. FIG. 15, panel (a) shows that the peak of the fluorescence ratio becomes narrow when two miRNA activities positively correlate with each other. FIG. 15, panel (b) shows that the peak of the fluorescence ratio becomes wide when two miRNA activities negatively correlate with each other. FIG. 15, panel (c) shows that an intermediate width peak can be formed when two miRNA activities do not correlate with each other.

FIG. 13, panel (d) shows the results obtained by performing a separation analysis on NHLF, using reporter mRNAs (α(miR-106a-5p)-hmAG1 (SEQ ID NO: 116), α(miR-21-5p)-hmKO2 (SEQ ID NO: 159), and α(miR-143-3p)-tagBFP) responding to three miRNAs, which have negatively correlated, or have not correlated with one another, in terms of miRNA activity. A cell population, into which the mRNAs have been introduced, is shown in the form of the density distribution of the fluorescence ratio.

FIG. 13, panel (e) shows the results obtained by performing a separation analysis on NHLF, using reporter mRNAs (α(miR-20a-5p)-hmAG1 (SEQ ID NO: 111), α(miR-17-5p)-hmKO2 (SEQ ID NO: 12), and α(miR-106a-5p)-tagBFP (SEQ ID NO: 171)) responding to three miRNAs, which have positively correlated with one another, in terms of miRNA activity. A cell population, into which the mRNAs have been introduced, is shown in the form of the density distribution of the fluorescence ratio.

As demonstrated in FIG. 13, panels (d) and (e), even in a case in which the target is an identical cell population, the cells are indicated as an extremely homogeneous cell population (f), if an mRNA set for such miRNAs having high positive correlation is used. In contrast, if another miRNA set is used, the heterogeneity of the cells was observed (e). As such, miRNA-responsive mRNAs to be used can be selected, depending on the purpose of distinguishing desired cells. For example, in this case, in a case in which NHLF is considered to be desired cells and NHLF is distinguished from other cells, by using an mRNA set for miRNAs having high positive correlation, the desired cells can be narrowed to a cell population with a narrow width (a specific cell population). When a wide variety of NHLF cells are considered to be a cell population comprising desired cells and the desired cells are separated and fractionated from the cell population, by using an mRNA set for miRNAs having high negative correlation, a desired portion can be collected from the widely distributed cells.

Example 11: Determination of Cell Population of IMR-90, Using miRNA-Responsive Reporter mRNA

The same second screening as that for NHLF was carried out on the established fibroblasts, IMR-90. In this experiment, the numbers 1 to 8, which show the miRNAs shown in FIG. 13, panel (c), successively indicate miR-16-5p, miR-17-5p, miR-125b-5p, miR-93-5p, miR-20a-5p, miR-106a-5p, miR-145-5p, and miR-26a-5p. Regarding each miRNA combination, a pair of reporter mRNAs responding to the miRNAs (SEQ ID NO: 117, 100, 125, 80, 157, 166, 174, 83, 167, 158, 175, 111, 161, 170, 178, 110, 116, 162, 171, 179, and 146 to 156) was introduced into IMR-90, and the peak width (90% interval) of the fluorescence ratio created by the cell population was analyzed. This peak width is shown in the following Table 7 as a relative value to the peak width obtained by the same analysis when control mRNA has been introduced into cells.

TABLE 7 relative 90% interval miR-145-5p miR-125b-5p miR-26a-5p miR-16-5p miR-17-5p miR-20a-5p miR-93-5p miR-106a-5p miR-145-5p 0.87 0.93 1.16 1.32 1.24 1.06 1.26 miR-125b-5p 0.88 1.13 1.16 1.13 1.06 1.18 miR-26a-5p 1.26 1.28 1.39 1.25 1.39 miR-16-5p 1.11 1.08 1.03 1.02 miR-17-5p 0.87 0.89 0.93 miR-20a-5p 0.76 0.82 miR-93-5p 0.77 miR-106a-5p

FIG. 16 shows the results obtained by selecting four types of miRNA-responsive mRNAs (α(miR-16-5p)-hmAG1 (SEQ ID NO: 80), α(miR-26a-5p)-hmKO2 (SEQ ID NO: 148), α(miR-17-5p)-tagBFP (SEQ ID NO: 167), and α(miR-125b-5p)-hdKeimaRed (SEQ ID NO: 153) based on the results of the second screening, and then co-introducing the four types of miRNA-responsive mRNAs into IMR-90, wherein the results are shown in the form of a three-dimensional density plot. As indicated with the arrows A and B shown in the figure, it has been found that the IMR-90 is separated into two cell groups.

REFERENCES

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What is claimed is:
 1. A method for distinguishing a desired cell type from a cell group comprising two or more types of cells, using the expression of miRNA as an indicator, wherein the method comprises the following steps: (1) a step of introducing mRNA comprising a marker gene operably linked to a target sequence of miRNA used as an indicator into a cell group; and (2) a step of distinguishing a cell type, using the translation level of the marker gene as an indicator.
 2. The method according to claim 1, wherein the step of introducing mRNA is carried out by an electroporation method.
 3. The method according to claim 1, wherein the target sequence of the miRNA is linked to the 5′- or 3′-terminal side of the marker gene.
 4. The method according to claim 3, wherein the step of introducing mRNA is carried out by an electroporation method.
 5. A method for producing an mRNA comprising a marker gene operably linked to a target sequence of miRNA used as an indicator, comprising: preparing a template DNA containing a promoter sequence; and synthesizing the mRNA from the template DNA using an in vitro transcription synthesis method.
 6. The method according to claim 5, further comprising step of designing the mRNA containing 5′-UTR, a coding region of the marker gene and 3′-UTR, in which target sequence of miRNA is contained in the 5′-UTR or 3′-UTR, and wherein the step of preparing the template DNA further comprises: preparing a template of the 5′-UTR, the coding region of the marker gene and the 3′-UTR; and linking the template of the 5′-UTR, the coding region of the marker gene and the 3′-UTR using a PCR primer. 